Name Reactions for Carbocyclic Ring Formations (Comprehensive Name Reactions)

Name Reactions for Carbocyclic Ring Formations

Wiley Series on Comprehensive Name Reactions Jie Jack Li, Series Editor

Name Reactions in Heterocyclic Chemistry Edited by Jie Jack Li Name Reactions of Functional Group Transformations Edited by Jie Jack Li Name Reactions for Homologation, Part 1 and Part 2 Edited by Jie Jack Li Name Reactions for Carbocyclic Ring Formations Edited by Jie Jack Li

Name Reactions for Carbocyclic Ring Formations

Edited by

Jie Jack Li Bristol-Myers Squibb Company Foreword by

E. J. Corey

Harvard University

WILEY A JOHN WILEY & SONS, INC., PUBLICATION

Copyright © 2010 by John Wiley & Sons, Inc. All rights reserved. Published by John Wiley & Sons, Inc., Hoboken, New Jersey. Published simultaneously in Canada. No part of this publication may be reproduced, stored in a retrieval system, or transmitted in any form or by any means, electronic, mechanical, photocopying, recording, scanning, or otherwise, except as permitted under Section 107 or 108 of the 1976 United States Copyright Act, without either the prior written permission of the Publisher, or authorization through payment of the appropriate per-copy fee to the Copyright Clearance Center, Inc., 222 Rosewood Drive, Danvers, MA 01923, (978) 7508400, fax (978) 750-4470, or on the web at www.copyright.com. Requests to the Publisher for permission should be addressed to the Permissions Department, John Wiley & Sons, Inc., I l l River Street, Hoboken, NJ 07030, (201) 748-6011, fax (201) 748-6008, or online at http://www.wiley.com/go/permission. Limit of Liability/Disclaimer of Warranty: While the publisher and author have used their best efforts in preparing this book, they make no representations or warranties with respect to the accuracy or completeness of the contents of this book and specifically disclaim any implied warranties of merchantability or fitness for a particular purpose. No warranty may be created or extended by sales representatives or written sales materials. The advice and strategies contained herein may not be suitable for your situation. You should consult with a professional where appropriate. Neither the publisher nor author shall be liable for any loss of profit or any other commercial damages, including but not limited to special, incidental, consequential, or other damages. For general information on our other products and services or for technical support, please contact our Customer Care Department within the United States at (800) 762-2974, outside the United States at (317) 572-3993 or fax (317) 572-4002. Wiley also publishes its books in a variety of electronic formats. Some content that appears in print may not be available in electronic formats. For more information about Wiley products, visit our web site at www.wiley.com. Library of Congress Cataloging-in-Publication Data: Name reactions for carbocyclic ring formations / edited by Jie Jack Li ; foreword by E.J. Corey. p. cm. Includes index. ISBN 978-0-470-08506-6 (cloth) 1. Ring formation (Chemistry) I. Li, Jie Jack. QD281.R5N36 2010 547'.2—dc22 2010008429 Printed in the United States of America. 10 9 8 7 6 5 4 3 2 1

Dedicated to Professor Keith R. Fagnou June 27,1971-November 11, 2009

Contents foreword Preface Contributing Authors

XV

Chapter 1 Three-Membered Carbocycles 1.1 Freund Reaction 1.2 Kishner Cyclopropane Synthesis 1.3 Kulinovich Cyclopropanol Synthesis 1.4 Simmons-Smith Cyclopropanation

1 2 7 13 25

Chapter 2 Four-Membered Carbocycles 2.1 Staudinger Ketene Cycloaddition

45 45

Chapter 3 Five-Membered Carbocycles 3.1 Danheiser Annulation 3.2 Dieckmann Condensation 3.3 Favorskii Rearrangement 3.4 Nazarov Cyclization Pauson-Khand Reaction 3.5 Weiss-Cook Reaction 3.6

71 72 93 109 122 147 181

Chapter 4 Six-Membered Carbocycles 4.1 Bardhan-Sengupta Pheantherene Synthesis 4.2 Bergman Cyclization Bogert-Cook Reaction 4.3 4.4 Bradsher Cycloaddition and Bradsher Reaction 4.5 Bradsher Reaction 4.6 Darzens Synthesis of Tetralin Derivatives 4.7 Diels-Alder Reaction Dötz Benzannulation 4.8 Elbs Reaction 4.9 4.10 Fujimoto-Belleau Reaction 4.11 Haworth Reaction 4.12 Moore Cyclization 4.13 Myers-Saito Cyclization 4.14 Robinson Annulation 4.15 Scholl Reaction

197 198 209 222 236 251 267 275 309 324 336 342 356 369 386 409

xi

VII

Vili

Chapter 5 Large-Ring Carbocycles 5.1 Buchner Reaction 5.2 de Mayo Reaction 5.3 Ring-closing Metathesis (RCM) 5.4 Thorpe-Ziegler Reaction

423 424 451 489 578

Chapter 6 Transformations of Carbocycles 6.1 Blanc Chloromethylation Reaction 6.2 Asymmetric Friedel-Crafts Reactions: Past to Present 6.3 Houben-Hoesch Reaction 6.4 Kolbe-Schmitt Reaction 6.5 Vilsmeier-Haack Reaction 6.6 von Richter Reaction

589 590 600 675 688 698 710

Appendices 1, 2, 3, 4, 5,

Contents Volume 1: 717 Name Reactions in Heterocyclic Chemistry Contents Volume 2: 720 Name Reactions for Functional Group Transformations Contents Volume 3: 722 Name Reactions for Homologations—Part I Contents Volume 4: 724 Name Reactions for Homologations—Part II Contents Volume 6: 726 Name Reactions in Heterocyclic Chemistry—Part II

Subject Index

729

Foreword

Part of the charm of synthetic organic chemistry derives from the vastness and multidimensionality of the intellectual landscape. First, there is the almost infinite variety and number of possible target structures that lurk in the darkness waiting to be made. Then there is the vast body of organic reactions that serve to transform one substance into another, now so large in number as to be beyond credibility to a nonchemist. There is the staggering range of reagents, reaction conditions, catalysts, elements, and techniques that must be mobilized in order to tame these reactions for synthetic purposes. Finally, it seems that new information is being added to that landscape at a rate that exceeds the ability of a normal person to keep up with it. In such a challenging setting, any author or group of authors must be regarded as heroic if through their efforts, the task of the synthetic chemist is eased. This volume on methods for formation of carbon rings brings to the attention of practicing synthetic chemists and students of chemistry a wide array of tools for the formation of such rings by synthesis. Since cyclic structures are among the most useful molecules, it is a valuable addition to the literature that will prove its merit for years to come. The new knowledge that arises with its help will prove to be of great benefit to humankind. E. J. Corey February 1,2010 ix

Preface

This book is the fifth volume of the series Comprehensive Name Reactions, an ambitious project conceived by Professor E. J. Corey of Harvard University in the summer of 2002. Volume 1, Name Reactions in Heterocyclic Chemistry, was published in 2005. Volume 2, Name Reactions for Functional Group Transformations was published in 2007. Volumes 3 and 4 on homologations were both published in 2009. They have been warmly received by the organic chemistry community. After this Volume 5, Name Reactions on Carbocyclic Ring Formations is out in 2010, we will roll out the final volume, Volume 6 on Name Reactions in Heterocyclic Chemistry—Part II, in 2011. Continuing the traditions of the first four volumes, each name reaction in Volume 5 is reviewed in seven sections: 1. Description, 2. Historical Perspective, 3. Mechanism, 4. Variations and Improvements, 5. Synthetic Utility, 6. Experimental, and 7. References. I also introduced a symbol [R] to highlight review articles, book chapters, and books dedicated to the respective name reactions. I have incurred many debts of gratitude to Professor E. J. Corey. What he once told me — "The desire to learn is the greatest gift from God" — has been a true inspiration. Furthermore, it has been my great privilege and a pleasure to work with a collection of stellar contributing authors from both academia and industry. Some of them are world-renowned scholars in the field, some of them have worked intimately with the name reactions that they have reviewed, some of them even discovered the name reactions that they authored in this series. As a consequence, this volume truly represents the state-of-the-art for Name Reactions for Carbocyclic Ring Formations. I welcome your critique.

Jack Li February 1,2010 xi

Jie Jack Li and E. J. Corey, circa 2002

Contributing Authors: Dr. Nadia M. Ahmad Takeda Cambridge 418 Cambridge Science Park Cambridge CB4 OPA United Kingdom

Dr. Paul Galatsis Medicinal Chemistry Pfizer Global Research & Development Eastern Point Road Groton, CT 06340

Dr. Jeffrey A. Campbell Department of Chemistry Lehigh University Bethlehem, PA 18015

Professor Brian Goess Department of Chemistry Furman University 3300 Poinsett Highway Greenville, SC 29613

Dr. Louis S. Chupak Discovery Chemistry Bristol-Myers Squibb Company 5 Research Parkway Wallingford, CT 06492

Dr. Martin E. Hayes Medicinal Chemistry Abbott Bioresearch Center 381 Plantation Street Worcester, MA, 01605

Dr. Timothy T. Curran Chemical Development Vertex Pharmaceuticals 130 Waverly Street Cambridge, MA 02139

Professor Nessan Kerrigan Department of Chemistry Oakland University 2200 North Squirrel Road Rochester, MI

Professor Roman Dembinski Department of Chemistry Oakland University 2200 North Squirrel Road Rochester, MI 48309

Dr. Ewa Krawczyk Department of Heteroorganic Chemistry Centre of Molecular & Macromolecular Studies Polish Academy of Sciences Sienkiewicza 112 90-363 Lodz, Poland

Dr. Matthew J. Fuchter Department of Chemistry Imperial College London London SW7 2AZ

Dr. Jie Jack Li Discovery Chemistry Bristol-Myers Squibb Company 5 Research Parkway Wallingford, CT 06492 XV

XVI

Noha S. Maklad Medicinal Chemistry Pfizer Global Research & Development Eastern Point Road Groton, CT 06340

Professor Kevin M. Shea Department of Chemistry Clark Science Center Smith College Northampton, MA 01063

Professor Richard J. Mullins Department of Chemistry Xavier University 3800 Victory Parkway Cincinnati, OH 45207-4221

Professor Nicole L. Snyder Hamilton College 198 College Hill Road Clinton, NY 13323

Dr. Kevin M. Peese Discovery Chemistry Bristol-Myers Squibb Company 5 Research Parkway Wallingford, CT 06492 Dr. Frank Rong ChemPartner No. 2 Building, 998 Halei Road Zhangjiang Hi-Tech Park, Pudong Shanghai, China 201203

Dr. Stephen W. Wright Medicinal Chemistry Pfizer Global Research & Development Eastern Point Road Groton, CT 06340 Dr. Yong-Jin Wu Discovery Chemistry Bristol-Myers Squibb Company 5 Research Parkway Wallingford, CT 06492

Name Reactions for CarbocycUc Ring Formations Edited by Jie Jack Li Copynght © 2010 John Wiley & Sons, Inc.

Chapter 1 Three-Membered Carbocycles

1

1.1 1.2 1.3 1.4

2 7 13 24

Freund Reaction Kishner Cyclopropane Synthesis Kulinovich Cyclopropanol Synthesis Simmons-Smith Cyclopropanation

Name Reactions Carbocyclic Ring Formations

1.1

F r e u n d Reaction

Frank Rong 1.1.1

Description

The Freund reaction refers to the formation of alicyclic hydrocarbons by the reaction of sodium on open chain dihalo compounds.1 1.1.2

Historical Perspective

In 1882 Freund reported that treating trimethylene glycol with hydrobromic acid gave trimethylene dibromide, which was further treated with sodium in reflux temperature. As a result the sodium dissolved, the sodium bromide was precipited, and a gas from the reaction was collected. What is the gas? By treacting with bromine it went back to trimethylene dibromide. By treacting with hydriodic acid it gave iodopropane. Therefore, the gas was concluded to be cyclopropane for the first time.1 This reaction has been called the Freund reaction on occasion. However, reference to the original literature shows that although Freund was the first to make cyclopropane itself, he used an extension of the Wurtz reaction and therefore had no claim to the method of ring closure that employs zinc in the presence of protonic solvent. Gustavson published in 1887 a paper titled "Concerning a New Method of Preparation of Trimethylene."2 Gustavson and Popper extended this method to the preparation of substituted cyclopropanes; using zinc dust-treated trimethylene dibromide gave cyclopropane.2'3 In 1936 Hass reported addition of sodium iodide to the zinc dust and 1,3-dichloropropane reaction mixture, both the yield of cyclopropane and the conversion rate were changed singnificantly. 1.1.3

Mechanism

The mechanism of Freund reaction is more likely as same as the Wurtz reaction, a free-radical mechanism. In the presence of iodide ions, the pathways might be a combination of substitution (SNI or SN2) with a freeradical mechanism.3

Chapter 1 Three-Membered Carbocycles Na Br'

3

Δ

~Br

Δ 1.1.4

Variations and Improvements

Gustavson reported a new method in the preparation of cyclopropane.2 Treating trimethylene dibromide (10 g) with zinc dust (12 g) suspended in aqueous alcohol at 50-60 °C gave cyclopropane. He tried different ratios of alcohol to water and found without water the reaction was very slow and at least 2% water was needed. Hass has further modified the Gustavson reaction condition.4 By using a large excess of zinc dust and by raising the temperature of the reaction mixture with high-boiling solvents, the rate of conversion was increased materially. When sodium iodide was added to a refluxing mixture of zinc dust, ethanol, and 1,3-dichloropropane, a marked acceleration of the reaction rate occurred. For example, using 1 mole of anhydrous sodium carbonate for each mole of 1,3-dichloropropane, a 100% excess of zinc dust, and 1/6 mole of sodium iodide in a solvent consisting of 75% ethanol and 25% water, a 95% yield of crude cyclopropane was obtained in 12 h in the same apparatus as before. A better yield and purer product were obtained if both sodium carbonate and acetamide were employed. The 1,3dichloropropane was prepared by the chlorination of propane obtained from natural gas. This is called as Hass cyclopropane process. 1.1.5

Synthetic Utility

The cyclopropane was an important anesthetic in 1930s. Galasso said: "The safest anesthetic agent—the one which presents all the good qualities and none of the objectional side effects of the agents we have on hand— cyclopane."5 This drug has been manufactured execusively by the following reaction sequence. 2HBr

Br'

^Br

+ 2 H,0

(1)

Name Reactions Carbocyclic Ring Formations

4

Zn (or Mg) -

A

+ ZnBr2 (or MgBr2)

(2)

The 1,3-propanediol (trimethylene glycol) was obtained as a byproduct of the soap industry, where it exists as a minor impurity in the glycerol. However, both 1,3-propanediol and hydrobromiic acid are relatively expensive compared to propane and chlorine.4 Hass process made the production of cyclopropane more cost effective. Shortridge and co-workers reported an extension of the Gustavson method for the synthesis of cyclopropane and its derivatives. They successfully prepared spiranes containing a cyclopropane ring and provide an easy, straightforward way of producing this type of hydrocarbon in quantity and in a good state of purity. The corresponding dibromide 1 was cyclized by zinc in aqueous ethanol to give spirane 2 in excellent yield. Br/>T^Br Ri R2

EtOH/H 2 0

-

R

^

Δ

1 HaC^V^^CH·, Yield:

3:92%

H0

CH3 OH

H C

/ \ ^ C H

7

CHa

H3C

CH,

4:94% ^ ρ Β ^ 3

H 3 C CH3CH3 Br-^-^Br

8

5:91% _Ξΐ

6:89% „

0 °C to r.t. n-PrOH / H20

H3C H3C^\7

9

The Freund reaction for the preparation of cyclopropane derivatives has in certain cases been unsatisfied due largely to the formation of olefins as the principal product. In general primary-primary 1,3-dibromides give high yields, primary-secondary dibromides give good yields. Secondarysecondary dibromides give fair yields, and all condensations involving a tertiary bromide give products containing an olefin as the principal or sole product. Bartleson and co-workers found that this problem can be solved at low terperature for the ring closure reaction.7 The 1,1,2trimethylcyclopropane 9 was prepared from 2-methyl-2,4-dibromopentane 8 by the Freund reaction at low temperature. The yield of crude product was

Chapter 1 Three-Membered Carbocycles

5

86% and the purity can reach 95% by fractional distillation in a high efficiency distilling column. The l,2-dimethyl-3-ethylcyclopropane 12 was similarly synthesized from 3-methyl-2,4-dibromohexane 11.7 A yield of 90% was obtained in the ring closure step. The secondary-tertiary and secondary-secondary 1,3dibromides, 8 and 11, were prepared in 90% yields by the reaction of phosphorus tribromide with the diols, 7 and 10, at low temperature (-24 °C). The low temperature prevents the loss of hydrogen bromide from the reaction mixture. OH H

OH

3 C " ^Υ ^ " CH 3

CH 3 {CHa

pBr3 3

Br"^Y^Br CH 3

CH

Zn

o°Ctor.t. n-PrOH/H 2 0

H

11

10

3C

x ^ ^ . ^CH,

12

1.1.6 Experimental Preparation of 1,1-dimethylcyclopropane (14)6 B r " X " ^Br H3C CH 3 13

Zn EtOH/H20

X

H3C

CH 3

14

In a 2 L three-necked flask equipped with a dropping funnel, mercury-sealed stirrer and reflux condenser (connected to a trap surrounded by a dry iceacetone bath) were placed 900 mL 95% ethanol, 90 mL distilled water and 628 g (9.6 mol) zinc dust; it was necessary to maintain vigorous stirring at all times to prevent caking of the zinc. The mixture was brought to gentle reflux, and 562 g (2.4 mol) of l,3-dibromo-2,2-dimethyl-propane 13 was added dropwise at the temperature. Heating and stirring were continued for 24 h after the last of the dibromide had been added; the bulk of the hydrocarbon collected in the trap during this period. The remaining 1,1dimethylcyclopropane (along with some alcohol) was then distilled from the reaction flask and was collected in the trap. The crude product 14 (162 g) was washed with ice water and dried. The product 12 was obtained in 96% yield (based on distilled dibromide) with these physical properties: b.p. 20.63 °C (760 mm) and «20D 1.3668.

6

Name Reactions Carbocyclic Ring Formations

Preparation of 1,1,2-trimethylcyclopropane (9)7 The reaction was carried out in a 1 L, three-necked flask fitted with a reflux condenser, thermometer, dropping funnel and mercury sealed stirrer. To the flask was added 100 mL water, 300 mL «-propyl alcohol and 196 g oxygenfree zinc dust prepared from commercial-grade zinc dust. The flask was placed in an ice-bath and 244 g (1 mol) of freshly distilled 2-methyl-2,4dibromopentane was added dropwise with efficient stirring over a period of about 90 min. The icebath was then removed and the mixture was stirred at room temperature for about 32 h. After about 10 h an immiscible layer of hydrocarbon had formed. At the end of the reaction the hydrocarbon product was separated by distillation. The crude product 9 was collected over a temperature range of 49-51 °C and weighed 78.1 g, a yield of 86%. The refractive index of the crude product was «20D 1.3847. The crude product was further purified by fractional distillation in a high-efficiency distilling column to give 95% pure product 9 with these physical properties: b.p. 52.1 °C (736 mm) and n2\ 1.3850. 1.1.7 References 1. 2. 3. 4. 5. 6. 7.

Freund, A. Monatsh. 1882, 3, 625-635. Gustavson, G. J. Prakt. Chem. (2) 1887, 36, 300-303. Gustavson, G.; Popper; J. J. Prakt. Chem. (2) 1898, 58, 458. Hass, H. B.; McBee E. T.; Hinds, G. E.; Gluesenkamp, E. W. Ind. Eng. Chem. 1936, 28, 1178-1181. Galasso, Anesth. and Anaiges. 1936,15, 32. Shortridge, R. W.; Craig, R. A.; Greenlee, K. W.; Derfer, J. M.; Boord, C. E. J. Am. Chem. Soc. 1948, 70, 946-949 Bartleson, J. D.; Burk, R. E.; Lankelma, H. P. J. Am. Chem. Soc. 1946, 68, 2513-2518.

Chapter 1 Three-Membered Carbocycles

1.2

Kishner Cyclopropane Synthesis

Frank Rong 1.2.1

Description

Kishner cyclopropane synthesis refers to the formation of cyclopropane derivatives 3 by decomposition of pyrazolines 2 formed by reacting α,βunsaturated ketones or aldehydes with hydrazine.1 1.2.2

Historical Perspective

In 1912 Kishner and Zavadovsku reported the synthesis of phenylcyclopropane by heating decomposition of 5-phenyl-3-pyrazoline.' The Kishner cyclopropane synthesis has become wellknown due to its unique and the smallest cyclic core structure.2 1.2.3

Mechanism

It is believable that the pyrazoline, 4 or 5, undergoes thermolytic decomposition and gives the diradicai 6 first. Then, the diradicai formed a bond quickly to give the cyclopropane 7. ' This could be a reversible reaction between the diradicai 6 and the cyclized product 7. R

^

2

R l ^ N C Ì ^ R 3 -NH 4

J

_

>v

R l^/N^ R N=N

R

22

. J

R..

XV ,R2

R_

^2 •R3

5

Stereochemical crossover in the pyrolysis of 3,5-disubstituted pyrazolines was proposed.3'4 The observation of a stereochemical crossover phenomenon stimulated a consideration of the mechanism from a different viewpoint. The loss of molecular nitrogen in the pyrolysis of a cis-3,5disubstituted pyrazoline, cis-8, might be expected to give a trimethylene

8

Name Reactions Carbocyclic Ring Formations

intermediate that could cyclized to a cw-disubstituted cyclopropane 10, if internal rotations were slow, or to a mixture of eis- and /raws-cyclopropanes, if internal rotations were fast. In the later case, the eis- and /raws-pyrazoline, 8 and 9, should give identical mixtures of cyclopropanes 10 and 11. The experimental facts, however, are inconsistent with either of these models since the stereochemistry of the cyclopropane product in each case is predominantly (3:1) opposite to that of the pyrazoline. Obviously, a stereorandomized trimethylene cannot be the sole intermediate. In fact, the stereochemistry of deazetation of pyrazolines is still not completely understood. H

H

H X%

H33 C ° \ / ' ' C H J3 N=N

Hó3C

c/s-8

CH 3 \ /'Ή ISFN

trans-9 major minor

minor H

H3C

CH 3

VVCH3

H3CT^H

10

11

The research groups of McGreer5,6 and Crawford7-11 have done comprehensive investigation on the cyclic azo compounds thermal decomposition. Crawford's group investigated the stereochemistry problem in the thermal decomposition of eis- and ira«s-3,5-dimethylpyrazolines (12 and 13).7 The major products of these decompositions are the stereoisomeric dimethylcyclopropane, and the major pathway is apparent single inversion of stereochemistry in each case. Crawford and Mishra rationalized these observations by assuming that the pyrazolines decompose in the envelope conformation leading directly to 0,0 intermediates. Predominant conrotatory closure then leads to overall single inversion of stereochemistry.7

H/,VY.»CH3 H3C

12) R1 = R3 = CH 3 and R2 = R4 = H 13) R-, = R4 = CH 3 and R2 = R3 = H

H

frans- 66.1% frans- 25.4%

+

Η/..Λ..,Η H3C

CH3

eis- 33.2% eis- 72.6%

Chapter 1 Three-Membered Carbocycles

9

One of the most difficult mechanisms to rule out rigorously involves the possibility than only one C-N bond breaks initially, leading (in the case of trans-pyrazoline 14 or 15) to diradicai 16. If the radical center at C-2 is now required to carry out a backside displacement of N2 at C-4, a product of the correct stereochemistry is produced.12 However, Crawford and his coworkers have carried out a number of elegant studied that provide support for a mechanism that involves simultaneous cleavage of both C-N bonds.7"11 H N-NH

Λ

"

V"H CH3

„CH 3

A

H 3 C*l^ " w

15

>H N2 16 H^/U

n

w

3^

17

/. 2.4

un

N=N

14 H 3 C*§

CH,

"'

a

H3C

18

CH3 19

Variations and Improvements

A couple of different approaches in the synthesis of pyrazolines were shown. Crawford and Ohno synthesized a 40:60 mixture of eis- and trans-3,5divinyl-1-pyrazoline, 21 and 22, by adding a concentrated solution of vinyldiazomethane 20 in diethyl ether, purified by distillation, to a large excess of 1,3-butadiene maintained as a liquid in a pressure bottle at low temperature.8 The intermolecular 1,3-cycloaddition of the diazoalkane proceeded more rapidly than the intramolecular cyclization to pyrazole. The kinetic of the thermolysis of these compounds in diphenyl ether at 35-65 °C producing divinylcyclopropane 23 were studied by measuring the rate of nitrogen evolution. They concluded that both carbon-nitrogen bonds are being broken in the rate determining step.8 ©Θ N=N H2

°

20

butadiene ^ /

N=N y *

<^l

N=N

-80 °C 21

22

\j,

Ph20 heat

II 23

The eis- and fran,s-3-ethyl-5-vinyl-l-pyrazoline, 25 and 26, were similarly prepared by the cycloaddition of 1-diazopropane 24 to 1,3butadiene. The mixture of cis-25 and trans-Id (18% eis, 82% trans, by NMR) was heated at 120 °C for 2 h. The product proportions were

Name Reactions Carbocyclic Ring Formations

10

determined by GC to be 57% eis- and 43% ira«5-ethyl-2-vinylcyclopro-pane, 27 and 28, respectively.

ΘΘ

=N=N

H,C-

butadiene

N=N

H3C.

1

24

+

V //

H3CN Jt

N=N

25 eis I trans =18/82 Ph20 120 °C, 2h

CH3

^

+

\

n

^

26

f

CH3

27 28 eis I trans = 57/43

7.2.5

Synthetic Utility

A great attention has been paid on the cyclopropane derivatives after Kishner reported his discovery due to the similarities between olefins and cyclopropane with respect to both their chemical and physical properties. ' Cyclopropane resembles ethylene in some respects, and both systems can enter into conjugation with other unsaturated groups such as a carbonyl group, a phenyl group, or a pyridyl group. Smith and Rogier synthesized the 2-phenylbicyclopropyl by the Kishner method.13 The styryl cyclopropyl ketone 29 was converted to pyrazoline 30, which was decomposed at 220 °C to give the 2-phenylbicyclopropyl 31 in 74% yield. The physical and chemical properties of this compound were also studied. The results indicated that this compound does not exhibit any of the conjugative effect shown by phenylcyclopeopane.

29

30

31

Mishra and Crawford reported the synthesis of (3R,5R)-(+)-trans-3,5dimethyl-1-pyrazoline 35 by different approach starting from alcohol 32.7 The pyrazoline 35 undergoes thermolysis, producing 25.6% of trans-1,2dimethyl-cyclopropane 36, processing 23% optical purity, and having the SV·!) configuration.

Chapter 1 Three-Membered Carbocycles H

1)Hg(OAc) 2

0H

5 HHsN 5N u o

33 (2R : 4R)

DN2H4

N=N

_Nz

Λ

Π H3 3 C ^ \ X ' " Cυ ΠH33

°

3 " ^H»C° ^

^

35 (3R:5R)

Bf

c

H CH 3 OH

32

2) Na2MC03 3)HgO

PBr5

HO^^-CH3

H '"CH3 2)NaBH 4

11 CH 3

^
H 3U Π H.CTH

34 (2S : 4S) Λ

t

^
36 (1S:2S)

B rΓ Η

% 3 ,Ο^ C^ ^Η ^

3

37(1R:2S)

Crawford and Tokunaga synthesized 3,3,5,5-tetramethyl-4methylene-1-pyrazoline 41 by a different approach.10 The tetramethyl-4pyrazolidone 39 was prepared by the reaction of hydrazine with α,α'dibromodiisopropylketone 38. Then oxidizing 39 by Mn02 gives intermediate 40, which was converted to 41 by following Mock's procedure.14

O

H3CX X

fH3

CH 3 CH 3

N2H4

H3C Η 3

o

U CH3

Mn0 2

°ΗΝ-ΝΗ3

38

N_N

39 Ph 3 PCH 2

°

HgC^J^CHa

40 Η 3

CH 2 3 < \ U CH 3 N=N

ό

41

They also studied the thermolysis of the compound 41.10 They found the thermolysis of 41 proceeds at 1/63 the rate of 4-methylene-l-pyrazoline. The 41 is undergoing thermolysis by a mechanism different from that for 4methylene-1-pyrazoline. The 2,2,3,3-tetramethylmethylenecyclopropane 42 produced rapidly isomerizes under the reaction conditions to 2,2dimethylisopropylidenecyclopropane 43. The four opposed methyl groups of 42 have created sufficient ground state destabilization as to cause its isomerization to be 147 times faster than the conversion of 2,2dimethylmethylenecyclopropane 44 to isopropylidenecyclopropane 45.

12

Name Reactions Carbocyclic Ring Formations 41 /

\

CH2

H 3 C Vv /CH 3

II Π 3 \J ^J_V*^ w Π 3 H3C

Ä-CH3

CH3

CH3

42

43 H3C\^CH 3

2

A

CH3 44

45

/. 2.6 Experimental Preparation of phenylcyclopropane 47.15 //

\

/. HN'N 46

heat -N 2

47

A mixture of 118 g 5-phenyl-3-pyrazoline 46, prepared by published procedure; 30 g pulverized potassium hydroxide; and 2.5 g platinized asbestos was heated in a 1 L, three-necked flask equipped with a stirrer and a Claisen distillation head. The temperature was raised slowly and the heat was shut off at the first sign of reaction. When the exothermic reaction ceased the temperature was again raised and the product was distilled. Both the distillate and the residue were steam distilled and the steam distillate was taken up in ether and dried first with sodium sulfate and then with sodium and redistilled. The product 47 was collected at 60-63 °C (11 mm Hg) and was finally redistilled giving a colorless oil, 11.5 g (12%), b.p. 173.5 °C (740 mm Hg), and «20D 1.5320. Preparation of 2-phenylbicyclopropyl (31)13 Preparation of 3-cyclopropyl-5-phenyl-2-pyrazoline (30): Styryl cyclopropyl ketone 29 (42 g, 0.245 mol) was added to a solution of aqueous hydrazine (25 mL, 0.42 mol) in ethanol (95%, 70 mL); the mixture became

Chapter 1 Three-Membered Carbocycles

13

warm and acquired a green color. It was allowed to stand for 45 min., then warmed on the steambath for 1 h, after which excess hydrazine and solvent were removed under reduced pressure. Distillation of the residue gave 30 as a light green liquid (37.8 g, 86%), which boiled at 164 °C (1 mm Hg). Preparation of 2-phenylbicyclopyl (31): Powdered potassium hydroxide (7.2 g) and platinized asbestos (3.2 g) were placed in a 100 mL round-bottomed flask arranged for distillation, and immersed in a metal bath. The bath was heated to 220 °C (thermometer in the bath), and the pyrazoline 30 (38.8 g, 0.2 mol) was slowly added. After the rapid evolution of nitrogen cased, the product 31 was distilled from the reaction mixture; it distilled at 92-96 °C (0.8 mm Hg), and weighed 22.5 g (74%). The products from several runs were combined and fractionated through a column (15 x 1.5 cm) packed with glass helices. A center cut was taken for analysis. This boiled at 57 °C (0.12 mm), and had n90 D 1.5352, a 904 0.9587, and molar refraction 51.40. 1.2.7 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15.

References Kishner, N. M.; Zavadovskii, A. J. Russ. Phys. Chem. Soc. 1912, 43, 1132. [R] Berson, J. A. in Rearrangements in Ground and Excited Slates vol. 1, P. de Mayo, Academic Press, New York, 1980, pp 326-329. [R] Bergmann, R. G. in Free Radicals, vol. 1, J. Kochi, Wiley, New York, 1973. Pp 191230. Crawford, R. J.; Mishra, A. J. Am. Chem. Soc. 1965, 87, 3768. McGreer, D. E.; Chiù, N. W. K.; Vinje, M. G.; Wong, K. C. K. Can. J. Chem. 1965, 43, 1407. McGreer, D. E.; McDaniel, R. S.; Vinje, M. G. Can. J. Chem. 1965, 43, 1389-1397. Mishra, A.; Crawford, R. J. Can. J. Chem. 1969, 47, 1515-1519. Crawford, R. J.; Ohno, M. Can. J. Chem. 1974, 52, 3134-3139. Crawford, R. J.; Erickson, G. L. J. Am. Chem. Soc. 1967, 89, 3907. Crawford, R. J.; Tokunaga, H. Can. J. Chem. 1974, 52,4033-4039. Crawford, R. J.; Mishra, A. J. Am. Chem. Soc. 1966, 55, 3963. Roth, W. R.; Martin, M. Ann. 1967, 702, 1. Smith, L. I.; Rogier, E. R. J. Am. Chem. Soc. 1951, 73, 3840-3842. Mock, W. L. Ph.D. thesis, Harvard University, Cambridge, MA, 1964. Hammond, G. S.; Todd, R. W. J. Am. Chem. Soc. 1954, 76,4081^1083.

14

1.3

Name Reactions Carbocyclic Ring Formations

Kulinkovich Cyclopropanol Synthesis

Jie Jack Li 1.3.1

Description 0

X

2 equiv. EtMgBr

R

1

0.1eq.Ti(/-PrO)4

\7

THF/Et 2 0(4:1)

2

Kulinkovich cyclopropanol synthesis, also known as Kulinkovich reaction or Kulinkovich cyclopropanation, is titanium-catalyzed transformation of esters 1 to its corresponding cyclopropanols 2.1 9 The EtMgBr/Ti(7-OPr)4 mixture resulting in bis-ethoxytitanacyclopropane is known as the Kulinkovich reagent, which is considered a synthetic equivalent of a two-carbon-1,2dianion synthon ( e CH 2 CH 2 e ). /. 3.2

Historical Perspective

Professor Oleg Grigor'evich Kulinkovich,10 a student of I. G. Tischenko of the Tischenko reaction fame, discovered the titled reaction in 1989 at Belorussian State University.11^14 The unprecedented transformation has received great attention and utility, as testified by the references cited herein. 1.3.3

Mechanism

Kulinkovich himself proposed that the dialkoxytitanacyclopropanes as the Extensive key intermediate in the Kulinkovich cyclopropanation.1 theoretical study on mechanism was published in 2001. 15 Eisch also provided detailed exploration of the mechanism for the Kulinkovich reaction in 2003. 16 In 2007, Kulinkovich proposed a modified "ate" complex mechanism for titanium-mediated cyclopropanation of carboxylic esters with Grignard reagents.17 Summing up the state-of-the-art understanding, the mechanism may be described as the following: When Ti(0/-Pr)4 was mixed with the ethyl Grignard reagent, they react to provide diethyl titanium intermediate 3, which immediately undergoes ß-elimination with formation of the titanacyclopropane 4 and with release of ethane gas. Next, a nucleophilic attack at the ester carbonyl furnishes the titanoxacyclopentane 5. Rearrangement to the homoenolate with concomitant activation of the carbonyl group allows for an intramolecular attack of the titanium-carbon

Chapter 1 Three-Membered Carbocycles

15

bond to give the titanium cyclopropane alkoxide 6. Metal exchange reaction with excess of Grignard reagent liberates the product as the magnesium alkoxide 7 and regenerates the catalytically active species 3.

H3C CH3

2EtMgBr /-PrOMgBr Ti(;-PrO)4

► (R 3 0) 2 Ti

-CH3

3, R3 = /-Pr or R2

2

H+

+ R3OH 3, R3 =/-Pr or R2

1.3.4

Ri

OMgBr

* „ „ + R2OMgBr

EtMgBr

Variations and Improvements HQ 0.1 eq. CITi(i'-PrO)3, 2 eq. n-PrBr

H CH 3

4 eq. Mg, THF, 18-20 °C, 79%

Initially, the ethyl Grignard reagent was successfully employed in the prototypical Kulinkovich reaction. In 1994, Corey demonstrated that when chlorotitanium(IV) triisopropoxide was better suited for higher substituted Grignard reagents, such as «-butylmagnesium bromide, can be used.18 As exemplified by transformation 8 to 9, the reaction was completely diastereoselective to give the cz's-1,2-dialkylated cyclopropanol 9. Furthermore, Corey also carried out the preliminary studies of an enantioselective version of the cyclopropanol synthesis with promising

16

Name Reactions Carbocyclic Ring Formations

results. Employing a chiral TADDOL-based titanium reagent, 85:12 to 89:11 enantio-selectivity was achieved. The other significant variation of the prototypical Kulinkovich reaction is the so-called Kulinkovich-de Meijere reaction, where de Meijere extended the substrates from esters to amides.19'20 Other carboxylic acid derivatives including (cyclic) carbonate, imides, and nitriles also react with the key Kulinkovich intermediate. Szymoniak21 developed an efficient new synthesis of cyclopropanes via hydrozirconation of allylic ethers (e.g., using Cp2Zr(H)Cl) followed by addition of a Lewis acid (e.g., BF3»OEt2). Casey et al. further investigated the stereochemistry of this interesting cyclopropanation reaction using deuterated allylic ethers. 9 FT^NBn 2 10

1.3.5

1. 2.5 eq. EtMgBr, 1 eq. Ti(/-PrO)4 2. -78 °C to 20 °C (THF) 3. H 3 0 +

\7 Rr"NBn2 11

Synthetic Utility

1.3.5.1

General Utility

In general, esters, acid chlorides, and anhydrides are most reactive toward the Kulinkovich reagent. Carbonates and thioesters are of moderate reactivity, whereas carbonamides are least reactive. Case in point was made by chemoselective Kulinkovich reaction of succinic ester-amide 12. Cha observed that only the ester portion underwent the Kulinkovich reaction to afford cyclopropanol 13. Szymoniak24 demonstarted that nitriles are more reactive than ester and amides.

"0'

°

" - " ^f 12 O

^

Ù / ^

^-""^OTIPS

c-C5H9MgCI 0.8 eq. (/-PrO)3TiCI rt, 58%

HO I *■

Γ "\

O 13

I OTIPS

Cha's group was among the earlier researchers to investigate and extend the utility of the Kulinkovich reaction. Employing 4-alkoxybutyyl Grignard reagents such as 15 (several other Grignard reagents such as 2phenethylmagnesium bromide did not work) and chlorotitanium(IV) triisopropoxide converted cyclopropanol 16 as a single diastereomer.25

Chapter 1 Three-Membered Carbocycles

C02Me

TIPSO

14

15

17 HQ

,MgCI

16 OTIPS

(/-PrO)3TiCI, 60%

An important contribution from Sato and Cha was their successful extension of the Kulinkovich reaction to the intramolecular version. For instance, reductive coupling of carboxylic ester 17 with a terminal olefin provided bicyclo[3.1.0]hexan-l-ol (18) in 71% yield.27 Cha also extended the low-valent titanium-mediated cyclopropanation to vinylogous esters as substrates. An interesting application is an intramolecular version of the methodology that transformed vinylogous ester 19 with a pendent terminal olefin to tricycle 20.28 OH n-BuMgCI, (/-PrO)3TiCI ether, rt, 6.5 h, 71%

17

H

18

c-C5H9MgCI, Ti(0/-Pr)4 then F^B-EtoO

OMe

OMe

20

19

Cha also explored substrate directed asymmetric synthesis using the Kulinkovich reaction. Sequential treatment of homoallylic alcohol 21 with Ti(0/-Pr)4 and c-CsHgMgCl furnished the putative intermediate 22, which upon exposure to ethyl acetate produced trans-l,2dialkylcyclopropanol 23 in 12.2 : 1 dr.29

0/-Pr

c-C5H9MgCI

tol., rt

THF, rt

OEt

-Ti-0 22

Ti (0/-Pr)4

Ph

23, dr= 12.2: 1

Name Reactions Carbocyclic Ring Formations

18

Sato and colleagues discovered a new titanium complex, (η propene)Ti(0/-Pr)2 (24), generated in situ, by treatment of Ti(0/-Pr)4 with 2 equiv of z'-PrMgX. Compond 24 was proven to a versatile reagent in synthetic reactions involving alkynes. At the onset of the investigation, the Sato group soon discovered that use of /-PrMgX as the Grignard reagent was very important for generating a titanium compound that afforded alkynetitanium complexes by the reaction with alkynes.30 When silyl alkyne 25 was treated with 24, the putative complex 26 was formed. Exposure of 26 to cyclopentyl aldehyde was followed by iodine to afford adduct 27 in 71% yield. An intramolecular version of the aforementioned transformation has been developed. Therefore, intramolecular coupling of diyne 28 provided [5,6]-bicyclic cyclopentadienol 29.31 SiMe

r

3

u

1 eq. Ti (0/-Pr)4 2 eq. /-PrMgCI

Me3Si ». r

VT./rt.„N jj>Ti(0/-Pr)2 J 26

25 Lc-CsHnCHO 2. I,

Me3Si C6Hi

equiv Ti (0/-Pr)4 2 equiv /-PrMgCI 85%

29

In addition, Sato et al. developed an interesting enantioselective synthesis of bicyclic cyclopropanols 31 from iV-acylcamphorsultam (the Oppolzer's chiral auxiliary) derivatives 30.32

2 eq. Ti (0/-Pr)4 4 eq. /-PrMgCI 56-87%

•ϋ HO,

31,c/r>92:8 ee > 98%

Chapter 1 Three-Membered Carbocycles

EtMgBr Ti(/-PrO)4 THF/Et20

OTHP 32

19

HN' OH OTHP 33

In the realm of medicinal chemistry, cyclopropanol provides a unique rigidity for the side chain. For instance, cyclopropanol 33, from ester 32, was 33 incorporated into nucleoside 34, an analogue of acyclovir. Similarly, ester 35 was converted to cyclopropanol 36, which was assembled onto guanine 34 37, an anti-HBV agent. EtMgBr, 0.25 eq. Ti(0/-Pr)4

TBDPSO 35

TBDPSO

THF, 0to25°C, 10 h, 80%

36

OH

OH

H P N ^ N ^ N

37 0=P-OH OH

1.3.5.2

Applications in the total synthesis of natural products

Ollivier and co-workers used the Kulinkovich reaction in their total synthesis ofheliannuolsKandL. 35,36 Thus, conversion of ester 38 with pendent olefin to cyclopropanol 39 was achieved using bromotitanium(IV) triisopropoxide and cyclohexyl Grignard reagent. Cyclopropanol 39 then underwent oxidation using FeCU and dechlorination to yield benzoxocinone 40, an intermediate for both heliannuols K (41) and L.

c-CsHgMgCI, (/-PrO)3TiBr ■ ■

■-

^O. *

■■■

-OH

·

THF, rt, 1 h, 43% 39

Name Reactions Carbocyclic Ring Formations

20

Singh's group converted ester 42 to its corresponding cyclopropanol 43, which was treated with NBS and then Et3N to deliver enone 44 via the intermediacy of ß-bromoketone.37 Enone 44 was transformed to tarchonanthuslactone 45. TBSO

EtMgBr, Ti(0;-Pr) 4

TBSO

Et 3 N, 95%

Corey employed the Kulinkovich reaction in the total synthesis of ßananeosene (48)/38δ Ester 46 was converted to cyclopropanol 47, which served as the substrate to make cyclobutanone by treating 47 with Al(Me)3.

EtMgCI, (/-PrO)3TiCI THF, 0 to 23 °C, 48 h, 60%

21

Chapter 1 Three-Membered Carbocycles

1.3.5.3

Utility of the Kulinkovich-de Meijere reaction

O

I-AN

c-C5H9MgCI, (;-PrO)3TiCI THF, 52%

Joullié took advantage of the Kulinkovich-de Meijere reaction and synthesized a series of constrained jV.TV-dialkyl neurotransmitter analogues. For instance, indolylcyclopropylamine 50 was assembled from indole-olefin 49 and DMF in 52% yield. While intermolecular Kulinkovich-de Meijere reaction assembles cyclopropylamine, many have taken advantage of a pendent olefin at the substrates to synthesize bicycles. Cha converted olefinyl amide 51 to bicyclic amine 52 in excellent yields.40 Six and co-workers prepared eight bicyclic aminocyclopropanes including 54 (from substrate 53) with yields ranging from26to87%.41'42 R

OTIPS

Ti(0/-Pr) 4 c-C5H9MgCI

2-N'R3

80-95%

1.5 eq. Ti(0/-Pr) 4 4 eq. c-C5H9MgCI THF, 20 °C, 37%

1.3.6 Experimental 1.3.6.1 Intramolecular Kulinkovich cyclopropanation reaction of 43 carboxylic ester with olefin: bicyclo[3.1.0]hexan-l-ol (2) OH ) 2 Me 17

n-BuMgCI, (/-PrO)3TiCI ether, rt, 6.5 h, 7 1 %

H

18

Name Reactions Carbocyclic Ring Formations

22

To a 500-mL, round-bottomed flask, equipped with a magnetic stirring bar and rubber septum, is added at room temperature a mixture of 2.0 g (15.6 mmol) of methyl 5-hexenoate (17, 11.2 mL, 11.2 mmol) of a 1 M solution of chlorotitanium triisopropoxide in hexane, and 54 mL anhydrous ether under a nitrogen atmosphere. A 1 M solution of n-butylmagnesium chloride in ether (52 mL, 52 mmol) is added over a period of 6.5 hr via a syringe pump at room temperature. After the addition is complete, the resulting black reaction mixture is stirred for an additional 20 min. The mixture is cooled to 0 °C with an ice bath, diluted with 50 mL ether and then quenched by slow addition of water (14 mL). The resulting mixture is stirred for an additional 3 h at room temperature. The organic phase is separated and the aqueous phase is extracted with ether (3 x 100 mL). The combined organic extracts are washed with brine (2 χ 50 mL), dried over anhydrous magnesium sulfate, filtered, and concentrated under reduced pressure using a rotary evaporator. Purification of the crude product by column chromatography on 40 g silica gel using a gradient of 5% to 10% ether/pentane as the eluent provides 1.09 g (71%) of bicyclo[3.1.0]hexan-l-ol (18) as a colorless oil. 1.3.6.2 Inter molecular Kulinkovich cyclopropanation reaction of carboxylic ester with olefin: frans-2-benzyl-l-methylcyclopropan-l-ol (56)43 _

^ ^

Ph

55

CH 3 C0 2 Et c-C 5 H 9 MgCI, (;-PrO)3TiCI ether, rt, 3 h, 80%

CH 3 HO—jL

U>

/Ph

56

To a 500 mL, round-bottomed flask, equipped with a magnetic stirring bar and rubber septum, is added a mixture of 2.5 g (21 mmol) allylbenzene (55, 2 mL, 20 mmol) ethyl acetate, 20 mL of a 1 M solution of chlorotitanium triisopropoxide in hexane, and 160 mL anhydrous tetrahydrofuran (THF). After the mixture has been cooled to 0 °C with an ice bath under a nitrogen atmosphere, a 1 M solution of cyclopentylmagnesium chloride in ether (80 mL, 80 mmol) is added over a period of 2.5 h via a syringe pump. After the addition is complete, the resulting black reaction mixture is stirred for 30 min at 0 °C, then is quenched by the cautious addition of water (15 mL). The resulting mixture is stirred for an additional 1 h at room temperature and filtered through a pad of Celite, which is rinsed thoroughly with ether (4 χ 50 mL). The combined filtrate and rinsings are poured into a separatory funnel containing 50 mL water and shaken thoroughly. The organic phase is separated, washed with brine (50 mL), dried over anhydrous magnesium sulfate, filtered, and concentrated under reduced pressure using a rotary evaporator. Purification of the crude product (obtained as a pale yellow oil)

Chapter 1 Three-Membered Carbocycles

23

by column chromatography on 80 g silica gel using 1:20 ethyl acetaterhexane as the eluent provides 2.6 g (80%) fra«s-2-benzyl-l-methylcyclopropan-l-ol (56) as a colorless oil. 1.3.7 References 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18. 19. 20. 21. 22. 23. 24. 25. 26. 27. 28. 29. 30. 31. 32. 33. 34. 35. 36. 37. 38. 39. 40. 41. 42. 43.

[R] Sato, F.; Urabe, H.; Okamoto, S. Pure Appi. Chem. 1999, 71, 1511-1519. [R] (a) Kulinkovich, O. G.; de Meijere, A. Chem. Rev. 2000, 100, 789-2834. (b) Kulinkovich, O. G. Pure Appi. Chem. 2000, 72, 1715-1719. [R] Sato, F. Urabe, H.; Okamoto, S. Synlett 2000, 753-775. [R] Sato, F.; Urabe, H.; Okamoto, S. Chem. Rev. 2000,100, 2835-2886. [R] Breit, B. J. Prak.Chem. 2000, 342, 211-214. [R] Eisch, J. J. J. Organomet. Chem. 2001, 617-618, 148-157. [R] Kulinkovich, O. G. Chem. Rev. 2003,103, 2597-2632. [R] Oestreich, M. Nac. Chem. 2004, 52, 805-808. [R] Tyvorskii, V. I.; Epstein, O. L. ARK1VOC 2008, 1-5. Kulinkovich, O. G.; Sviridov, S. V.; Vasilevski, D. A.; Pritytskaya, T. S. Zh. Org. Khim. 1989, 25, 2244-2245. Kulinkovich, O. G.; Sviridov, S. V.; Vasilevskii, D. A.; Savchenko, A. I.; Pritytskaya, T. S. Zh. Org. Khim. 1991,27, 294-298. Kulinkovich, O. G.; Sviridov, S. V.; Vasilevskii, D. A. Synthesis 1991, 234. Kulinkovich, O. G.; Sorokin, V. L.; Kel'in, A. V. Zh. Org. Khim. 1993, 29, 66-69. Kulinkovich, O. G.; Savchenko, A. I.; Sviridov, S. V.; Vasilevskii, D. A. Mendeleev Commun. 1993,230-231. Wu, Y.-D.; Yu, Z.-X. J. Am. Chem Soc. 2001,123, 5777-5786. Eisch, J. J.; Adeosun, A. A.; Gitua, J. N. Eur. J. Org. Chem. 2003,4721^1727. Kulinkovich, O. G.; Kananovich, D. G. Eur. J. Org. Chem. 2007, 2121-2132. Corey, E. J.; Rao, S. A.; Noe, M. C. J. Am. Chem. Soc. 1994,116, 9345-9346. Chaplinski, V.; de Meijere, A. Angew. Chem., Int. Ed. Engl. 1996, 35, 413^114. de Meijere, A.; Williams, C. M.; Chem. Eur. . 2002, 8, 3789-3801. Gandon, V.; Szymoniak, J. Chem. Commun. 2002, 1308-1309. Casey, C. P.; Strotman, N. A. J. Am. Chem. Soc. 126, 1699-1704. Lee, J.; Cha, J. K. J. Org. Chem. 1997, 62, 1584-1585. Bertus, P.; Menant, C; Tanguy, C; Szymoniak, J. Org. Lett. 2008,10, 777-780. Lee, J.; Kim, H.; Cha, J. K. J. Am. Chem. Soc. 1995,117, 9919-9920. Kasatkin, A.; Sato, F. Tetrahedron Lett. 1995, 36, 6079-6082. Lee, J.; Kim, H.; Cha, J. K. J. Am. Chem. Soc. 1996, 118,4198^1199. Masalov, N.; Feng, W.; Cha, J. K. Org. Lett. 2004, 6, 2365-2368. Takayanagi, Y.; Yamashita, K.; Yoshida, Y.; Sato, F. Chem. Commun. 1996, 1725-1726. Harada, K.; Urabe, H.; Sato, F. Tetrahedron Lett. 1995, 36, 3203-3206. Ollero, L.; Mentink, G.; Ruyjes, F. P. J. T.; Speckamp, W. N.; Hiemstra, H. Org. Lett. 1999, /, 1331-1334. Mizojiri, R.; Urabe, H.; Sato, F. Angew. Chem., Int. Ed. Engl. 1998, 37, 2666-2668. Esposito, A.; Taddei, M. J. Org. Chem. 2000, 65, 9245-9248. Choi, J.-R.; Cho, D.-G.; Roh, K. Y.; Hwang, J.-T.; Ahn, S.; Jang, H. S.; Cho, W.-Y.; Kim, K. W.; Cho, Y.-G.; Kim, J.; Kim, Y.-Z. /. Med. Chem. 2004, 47, 2864-2869. Lecornué, F.; Ollivier, J. Org. Biomol. Chem. 2003,1, 3600-3604. Lecornué, F.; Paugam, R.; Ollivier, i. Eur. J. Org. Chem. 2005, 2589-2598. Baktharaman, B.; Selvakumar, S.; Singh, V. K. Tetrahedron Lett. 2005, 46, 7527-7529. Kingsbury, J. S.; Corey, E. J. J. Am. Chem. Soc. 2005,127, 13813-13815. Faler, C. A.; Joullié, M. M. Org. Lett. 2007, 9, 1987-1990. Lee, J. C; Sung, M. J.; Cha, J. K. J. Am. Chem. Soc. 2001, 42, 11322-11324. Larquetoux, L.; Ouhamou, N.; Chiaroni, A.; Six, Y. Eur. J. Org. Chem. 2005,4654-4662. Chiaroni, A.; Six, Y. Org. Biomol. Chem. 2003,1, 3007-3009. Kim, S.-H.; Sung, M. J.; Jin, K. C. Org. Synth. 2003, 80, 111-119.

Name Reactions Carbocyclic Ring Formations

24

1.4

S i m m o n s - S m i t h Cyclopropanation

Matthew J. Fuchter 1.4.1

Description

The stereospecific addition of a metal carbenoid (mainly zinc based) to a double bond is known as the Simmons-Smith cyclopropanation.1 It is one of the most powerful methods of converting olefins to cyclopropanes. R1

R2

R4

R3

YMCH2X

Rv1

2

R

R 4 V R3

M = Zn, Sm, Al Y = alkyl, halide x = halide

The classical conditions use the zinc-copper couple (Zn-Cu) and diiodomethane to prepare the active carbenoid species, although there are alternative conditions (see 1.4.5.1), the most important being the Furukawa modification, which uses diiodomethane in the presence of diethylzinc. Samarium and aluminium carbenoids are also effective as cyclopropanating reagents (see 1.4.5.2). The reaction can be performed in a range of solvents, however, increased rates are observed in noncoordinating solvents such as dichloromethane. A wide range of alkenes can be used, including simple olefins, α,β-unsaturated systems, and electron-rich alkenes such as enol ethers. In general, the reaction conditions are highly tolerant of most functional groups. The reaction takes place stereospecifically whereby the stereochemistry of the double bond is preserved in the product. If a substituted methylene group is added to the double bond, in the majority of cases a syn product is observed. Many polar functional groups (OH, OAc, OMe, NHR) have a directing effect on the cyclopropanation either enabling regioselective reactions for substrates containing multiple double bonds, or stereoselectivity for chiral substrates. Asymmetric Simmons-Smith cyclopropanations are possible by either using stoichiometric chiral auxiliaries, or by the use of chiral catalysts (see 1.4.4.3.3). 1.4.2

Historical Perspective

In 1958, Howard Simmons and Ronald Smith reported a general method for preparing cyclopropane compounds from olefin substrates.7'8 For example, cyclohexene (3) was converted to cyclopropane 4 in moderate yield. The development of this method was built on earlier work by Emschwiller in

Chapter 1 Three-Membered Carbocycles

25

1929, who reported the preparation of diiodomethane and its reaction with the zinc-copper couple to form iodomethyl zinc iodide.9 In fact, even Emschwiller's studies were preceded by extensive work from numerous other chemists, with the reaction of diiodomethane and a variety of metals attracting attention ever since the 1860s. In the field of cyclopropane synthesis, the procedure developed by Simmons and Smith was particularly notable for its broad generality. At the time, the only other viable options were the classical addition of diazo compounds to olefins,10 or the production and use of dihalocarbenes."

o ~d Zn-Cu

3

48%

H

4

The only downside of this method was the irreproducibility of generating the active reagent from the zinc-couple and diiodomethane. Furukawa and co-workers provided one solution in 1966 when they showed that a mixture of diethyl zinc and diiodomethane gives very reproducible results in generating the active reagent (see 1.4.5.1 for this and other methods).12 It has subsequently been shown that other carbenoid species, including samarium13 and aluminium,14 are also effective reagents in the cyclopropanation reaction, and in some cases demonstrate interesting chemoselectivity. Nowadays, the Simmons-Smith reaction has developed into one of the most powerful methods of cyclopropane formation available to synthetic chemists. Indeed, in their 2001 review, Charette and Beauchemin documented all the examples of the Simmons-Smith reaction to appear in the literature between 1973 and 1999, and this totaled more than 1500 olefin substrates. Since the 1990s, the major developments in the Simmons-Smith reaction have focused on asymmetric methods to stereoselectively prepare chiral cyclopropanes. One of the most widely used methods in this regard originates from a report by Charette and co-workers in 1994 on the use of chiral dioxaborolane auxiliaries (see 1.4.4.3.2).15 1.4.3

Mechanism

Simmons-Smith cyclopropanation proceeds via the addition of a zinc carbenoid (6/8) to an olefin. There are three classes of reactions, however, that can generate the reactive zinc species, each with it is own mechanistic pathway.5 The oxidative addition of an activated form of zinc metal into a C X bond is by far the most widely used method for the formation of 6

Name Reactions Carbocyclic Ring Formations

26

(Pathway A). Indeed, it was this method that Simmons and Smith first used in their seminal study,7'8 with many methods of zinc activation available (see 1.4.5.1). Furukawa's modification of the reaction uses diethyl zinc, and proceeds via alkyl ligand exchange to give 8 (Pathway B). Finally, Wittig reported the insertion of diazomethane (7) into zinc iodide to give 6,16 although this method is not widely used. ZnX2

+

I^^ZrT^I

/ Znl2 N=N-CH 2 + 7

CI 1

CI /

Zn

,Ζη-

S

CI /

CH2

A;!

Path A: Oxidative addition Path B: Akyl ligand exchange Path C: Zn-I insertion

CI' H H

13

Zinc carbenoids 6 and 8 are in Schlenk equilibria with dialkyl zinc 9 and ZnX2, although the position of the equilibrium depends on the counter ligand X. Spectroscopic studies have shown that in the case of iodomethyl zinc iodide (6), the equilibrium lies strongly in favour of the active species 6.17'18 For ethyl-substituted carbenoid 8, however, Et2Zn and dialkyl zinc 9 are far more prevalent, and an additional self-destructive pathway is 17

apparent, giving rise to PrZnI. Since this destructive reaction can be competitive with cyclopropanation, in certain cases it may be advantageous to add additional diiodomethane (to convert PrZnI to the active species). After generation of the active species, the reaction proceeds via concerted addition of the methylene group to the olefin substrate with retention of configuration. This process was postulated to proceed via a three-centre "butterfly-type" transition state 11 on the basis of experimental observations, and numerous theoretical calculations are in agreement with this postulate.5 However this transition state may not be the favoured reaction pathway under all relevant experimental conditions. For example,

Chapter 1 Three-Membered Carbocycles

27

theoretical studies on the cyclopropanation of ethylene with chloromethylzinc chloride, in the presence of zinc chloride indicated the fivecentered complex 13 to be the kinetically favoured transition state.19 1.4.4 Synthetic Utility 1.4.4.1

Substrate Scope

The Simmons-Smith reaction is a broadly applicable procedure and has a wide-ranging functional group tolerance. In general, higher reactivity is observed with electron-rich alkenes, due to their increased nucleophilicity. Enol ethers are just one example of substrates whose cyclopropanation under the reaction conditions is generally facile. Silyl enol ethers are the most widely used in this regard since they are readily available from enolization of the corresponding ketone. For example, substrate 14 was converted to 15 in excellent yield using Furukawa's conditions (see 1.4.5.1).20 OTMS

OTMS OBn

CH2'2

OBn

Et2Zn 90%

The cyclopropanation of vinyl halides is also effective, with fluoro-, bromo- and iodo-substituted olefins all being suitable substrates. For example, vinyl bromide 16 underwent the reaction in good yield, using Denmark's modification of the reaction (see 1.4.5.1).21 CH 2 ICI, Et2Zn Br

16

DCE 69%

While the classical Simmons-Smith regent (Zn/Cu) is often used, Furukawa's conditions (Et2Zn/CH2l2, see 1.4.5.1) are the preferred choice for less reactive olefin substrates. This is since generation of the active carbenoid under Furukawa's conditions can be performed in noncomplexing solvents, which in turn, leads to a reagent with a higher electrophilicity.5 Taber and coworker's synthesis of /raws-dihydroconfertifolin (20) employed such conditions in their endgame strategy, cyclopropanating substrate 18 in

28

Name Reactions Carbocyclic Ring Formations 22

excellent yield. The resulting cyclopropane was subjected to catalytic hydrogenolysis to give /ra«s-dihydroconfertifoin (20). CH2l2(16equiv) Et2Zn (8 equiv) ; » PhMe, rt 92%

H2, Pt0 2 »> AcOH 99%

Me" Me 20: frans-Dihydroconfertifolin

1.4.4.2

Regioselectivity and Stereoselectivity

When more than one double bond is available to react within a substrate, a combination of both steric and electronic effects control the regioselectivity of cyclopropanation.5 In light of the electrophilic nature of the reagent, highly regioselective Simmons-Smith reactions are observed when one double bond is significantly more nucleophilic than another. For example, the high reactivity of enol ethers can be used to obtain excellent regioselectivity. Winkler et al. capitalized on such high regioselectivity in their conversion of substrate 21, into cyclopropane 22, a key derivative in the synthesis of taxol analogs.23 CH2ICI, Et2Zn DCE, 0 °C

TBSO" MeO 21

OTIPS

99%

TBSO"1 MeO 22

OTIPS

Polar functionality remote from the double bond can also be used to direct both the regioselectivity and stereoselectivity of the Simmons-Smith reaction. Much work has been performed on the directing effect of basic

Chapter 1 Three-Membered Carbocycles

29

functional groups in the allylic position of cyclic alkenes.5 Indeed, it was recognized early on that proximal hydroxyl groups can direct the cyclopropanation reaction.24 In general, cyclopropanation of five-, six-, and seven-membered ring l-cycloalken-3-ols proceed with high levels of syn selectivity.6 Such diastereoselectivity has been used to good effect, even with more complex substrates, such as the use of derivative 23 by Corey and coworkers.25 It is interesting that a switch in selectivity is observed with the analogous eight- and nine-membered ring systems. In these cases, high anti selectivity is often observed, a fact that can be readily rationalized by the conformation of the ground state molecule.6 i) n-BuLi (1 equiv) Et 2 0, -20 °C > ii)IZnCH 2 l (15 equiv) Et 2 0, rt

While the hydroxyl group has been most extensively used to direct the Simmons-Smith reaction, other basic groups such as ethers, esters and acetamides are also able to direct the zinc reagent in certain cases.5 For example, in the case of substrate 25, the unsubstituted acetamide (R = H) is a better directing group than the hydroxyl group, giving cyclopropane 27 as the sole stereoisomer. Once benzoylated however (25, R = Bz), the selectivity is reversed, resulting in the selective formation of compound 26.26 BnO

BnO HON

Ac

27

0 1

In the absence of a directing group, the cyclopropanation of cyclic olefins is generally under steric control. The stereochemical preference can be predicted from the ground state conformation of the molecule and often high levels of stereocontrol are observed. For example, Paquette and coworkers used a Simmons-Smith reaction in their total synthesis of the secondary marine metabolite (+)-acetoxycrenulide (30), whereby high ß-face selectivity was observed.

97

Name Reactions Carbocyclic Ring Formations

30

O

q RQ

,,Me

Q

28

Me

0

CH 2 I 2 , Et2Zn *PhH 92%

H , Λ ΛΗ vMe

RQ

H

29

0

Me

^/"X.vMe

Me ° V M e ^ ^ \ — '., OAc Me 30: (+)-acetoxycrenulide

The stereoselective Simmons-Smith reaction of a chiral acyclic allylic alcohol was first reported by Pereyre and co-workers in 1978. They observed very high syn selectivities (> 200:1) when (Z)-disubstituted olefins such as 31 were treated under classical Simmons-Smith conditions. The analogous reaction of (£)-olefins however was reported to only give modest selectivity (< 2:1). In depth studies by Charette and co-workers however has revealed that the nature zinc carbenoid used in these reactions is key to obtaining high selectivities.29'6 While in the case of simple (£)-disubstituted olefins, the classical Simmons-Smith conditions (Zn-Cu, CH2I2, Et20) gives only modest selectivity, the use of Furukawa's reagent (Et2Zn, CH2I2) in excess produces a much higher degree of selectivity, especially when dichloromethane is used as the solvent.29'6 Indeed, these trends are generally maintained for more complex acyclic systems, although it should be stated that stereoelectronic effects also play an important role.6 OH

CH2I2, Zn-Cu

OH

Et,0

31

32 syn.anti >99:1

Impressive regioselectivity and stereoselectivity has been reported for a number of complex acyclic systems, including the synthesis of halicholactone (35) by Takemoto and co-workers. In their total synthesis, substrate 33 was converted into the desired product 34 in good yield and total

Chapter 1 Three-Membered Carbocycles

31

selectivity.30,31 ' It is interesting that a hydroxyl group was required to direct the reaction (an acetal being ineffective), and the protecting groups used were crucial to its success. OSEM PivO

'C5H11

OH

33

OTBS

OSEM

Et2Zn, CH 2 I 2 CH 2 CI 2 ,-20°C 68%

'C5H11

PivO OH

34

OTBS

C5H11

35: halicholactone Me, Me

Zn-Cu CH 2 I 2

Mev Me >■

36

oX o

Et 2 0 35 °C, 6 h 60%

As is the case with cyclic substrates, other basic functional groups are able to effectively direct the reaction in certain cases. An impressive example was reported by Iwasaki and co-workers in their synthesis of the antimitotic agent (+)-curacin A (38), whereby an acetal oxygen was used to direct the reaction. In a two-directional approach, substrate 36 was converted into product 37 as a single diastereoisomer in good yield. This compound was subsequently deprotected and subjected to oxidative cleavage to give the desired 2-methylcyclopropane carboxylic acid, which was required to form the thiazoline portion of curacin A. Indeed, such a stereoselective twodirectional cyclopropanation of tartrate derived substrates had been

Name Reactions Carbocyclic Ring Formations

32

previously reported by Barrett and co-workers and used in their total synthesis of FR-900848.33'34 The stereocontrol in acyclic chiral olefins in which the basic directing group is not the stereogenic centre is generally quite poor.6 One exception to this rule however, was reported by Panek et al., who demonstrated that a stereogenic bulky silicon group in the allylic position of acyclic substrates can induce good diastereoselectivities.35 In terms of the synthesis of substituted cyclopropane derivatives using either halo- or alkyl-substituted reagents, endo:exo selectivity of the product is often poor.5 For example, cyclohexene (39) was converted into an approximately 2:1 ratio of 40 and 41 on exposure to bromoform and diethylzinc.14

39

CHBr3, Et2Zn »02 84%

H

5*

1.9

H

H

-Br + [ 40

Br 1

H 41

The use of directing groups is effective at controlling the relative stereochemistry of the cyclopropane and the directing functionality, however once again, endo:exo selectivity is usually modest. For example, relatively poor selectivity was observed in the conversion of substrate 42 into derivative 44, although the samarium-derived reagent (see 1.4.5.2) provided slightly better results. OH

! JH

JH

£> "'Me

-Me +

"H 43

42 Sm, MeCHI2 (> 99%) Et2Zn, MeCHI2 (64%) Zn-Cu, MeCHI2 (84%)

17 37 28

"H 44

83 63 72

As is usually the case, however, specific results are dependent on the substrate in question, and the selectivity observed a case of both steric and electronic factors. For example, in their enantioselective synthesis of (-)pinidine, Momose et al. reported a highly diastereoselective reaction employing the reagent derived from 1,1-diiodoethane and diethyl zinc 37 Substrate 45 was selectively converted to stereoisomer 46 in excellent yield

Chapter 1 Three-Membered Carbocycles

33

It is important to note, however, that the nitrogen-protecting group was crucial to the success of this reaction. Et2Zn OTMS CH3CHI2 TsN--^-^

CH2CI2

45 1.4.4.3

46

.f"Me

47

99%

„rH Me

Asymmetric Simmons-Smith Reactions

1.4.4.3.1

Chiral Auxiliaries

The use of a chiral auxiliary is one strategy of preparing enantiomerically pure cyclopropyl derivatives after cleavage of the auxiliary. There are several classes of auxiliary that have been used for different substrates, and these can be divided into chiral allylic ethers, acetals, α,β-unsaturated carbonyl derivatives, enamines, and enol ethers.6 In the case of chiral allylic ethers, carbohydrate derivatives have proved particularly effective, inducing excellent levels of diastereoselectivity in the reaction. For example, substrates of the general class 48, were cyclopropanated asymmetrically in excellent yield and very high levels of diastereoselectivity. 8 It is believed that the chiral auxiliary acts as a bidentate ligand for the zinc reagent, and indeed, structurally simplified auxiliaries are almost as effective.39 R1

ΒηΟ-Λ BnU

^^OH

48

\

R

Et2Zn(10equiv)

BnO^

CH2l2(10equiv)

B n 0

PhMe

^^H

> 95% yield > 98% d.e.

R1 49

P^ *3

A number of chiral acetal derivatives have also proved effective in asymmetric cyclopropanation reactions, with auxiliaries based on tartaric acid proving to be particularly useful.6 In the case of cyclic α,β-unsaturated compounds, di-O-benylthreitol derivatives (see 51) undergo efficient and diastereoselective Simmons-Smith reactions to give the cyclopropanated products 53. 40 The configuration of the products can be rationalized by model 52, whereby coordination of the zinc reagent occurs to the least sterically hindered dioxolane oxygen atom proximal to the olefin.

Name Reactions Carbocyclic Ring Formations

34

BnOH2C Ri

£H2OBn

0

0

CH2I2 (3 equiv) EtpO

2

R

51

BnOH2C

*~

|

53 1.4.4.3.2

vCH2OBn

Zn/Cu (> 6 equiv)

-►

50

BnOH2C

52

t : : : C H 2'

{

\/^R2

£Η 2 0Βη ><,R1 T;;<

54-95 % yield 88-95% d.e.

\ ^ R 2

Stoichiometric Chiral Ligands

As early as 1968, the addition of chiral ligands to the reaction was performed in an attempt to induce asymmetry.41 Despite several early attempts, however,6 only modest enantioselectivities were obtained. Fujisawa and coworkers reported the first moderate levels of asymmetric induction by adding stoichiometric amounts of diethyl tartrate to the Furukawa's Simmons-Smith conditions.42 In 1994, however, a major breakthrough was reported by Charette and co-workers, who demonstrated that bifunctional non-racemic chiral ligands induced good levels of enantioselectivity in the reaction.15 These ligands contained both acidic and basic sites that allowed simultaneous chelation of the acidic halomethylzinc reagent and the basic zinc alkoxide. In particular, dioxaborolane 55, prepared from 7V,7V,7V',./V'-tetramethyltartaric acid diamide and butyl boronic acid, was a particularly useful chiral controller. This stoichiometric ligand shows good substrate scope, and the products (56) are usually isolated in good yield and high enantiomeric purities. Me2NOC

0

R1 R2~V^OH

54

pONMez

/—\

Ov . 0

55 ? ° Bu

3

(1.1 equiv)

_ 2CI2 CH

ii) Zn(CH2l)2 (2.2 equiv) CH2CI2, 0 to 25 °C

R1

R 2 rf^^c 'i^^OH R3

56

Charette's procedure is so efficient that it has been used in numerous syntheses of complex molecules. For example, en route to (+)-ambruticin,

Chapter 1 Three-Membered Carbocycles

35

Jacobsen and co-workers used the Charette ligand to mediate asymmetry in the cyclopropanation of substrate 57.43 This reaction is particularly notable since a substituted cyclopropane is installed with high diastereoselectivity. CH3CHI2(10equiv) Et2Zn (5 equiv) CH2CI2, DME (R,R)-dioxaborolane 55 (1.2 equiv) -10 °C, 2h 86%

Me2NOC

55

£ONMe2

éu

Although other stoichiometric mediators of the Simmons-Smith reaction have been reported, such as biaryl alcohols44 and dipeptides,45 none have to date shown such broad applicability as the Charette ligand. 1.4.4.3.3

Sub-Stoichiometric Chiral Ligands

Several examples have been reported of asymmetric Simmons-Smith reactions whereby the chiral, nonracemic ligand is added in substoichiometric quantities. Kobayashi and co-workers were the first to report such a system, and showed that catalytic quantities of disulfonamide ligand 60 could result in isolation of the product (for example 62) in good enantioselectivity. 6 This method has broad applicability and results in consistently high enantioselectivities for a wide range of substrates.6 Denmark and co-workers subsequently reported an in-depth study of this reaction and highlighted that the rate and selectivity of the catalytic cyclopropanation greatly depends on the order of addition of the reagents.18 Preformation of the ethylzinc alkoxide and bis(iodomethyl)zinc was crucial and the reaction was shown to be autocatalytic due to the generation of zinc iodide. These and other observations led to the proposed transition state assembly 61, in which three zinc atoms are involved in the methylene delivery process.

Name Reactions Carbocyclic Ring Formations

36

ZnEt2, CH2I2 ►

59 60

X

^'/NHSO2Me (0.12equiv)

Ph

^

62

'

OH

92% yield 89% e.e.

Charette and co-workers reported a chiral Lewis acid-catalysed Simmons-Smith reaction, using a titanium TADDOL complex, although in general this system shows limited substrate scope compared to the Kobayashi system.47 i)ZnEt2(10mol%), CH2I2 (10mol%)

f"W A r

OR

0 Ui o 1mol% 0 0H f^vV 1 | |[ 64

Ph 63

ii) Zn(CH2l)2 (0.9 equiv) DME (0.54-1.2 equiv)

OR P h ^ ^

65 83% yield 88% e.e.

More recently, however, the group have developed chiral zinc phosphate reagents as mediators of the asymmetric Simmons-Smith reaction. A chiral, nonracemic zinc reagent derived from phosphoric acid 64 was shown to be effective for the enantioselective cyclopropanation of substrates 63 when used in stoichiometric quantities. After significant optimization, it was shown that modified conditions could allow the use of just 10 mol % of 64, resulting in the production of the product 65 with good levels of enantiomeric excess.4 Charette and co-workers have extended this work, developing alternative ligands such as a TADDOL derived phosphoric acid.49

Chapter 1 Three-Membered Carbocycles

1.4.5 1.4.5.1

37

Variations and Improvements Methods of generating active species

There are three classes of reaction that can generate the reactive haloalkylzinc species: (1) Oxidative addition of zinc metal into a carbonhalogen bond, (2) alkyl group exchange between and organozinc reagent and a dihaloalkane, and (3) the insertion of a diazoalkane into a zinc iodide bond. Class 1, oxidative addition The oxidative addition of activated zinc metal into a carbon-halogen bond is still one of the most widely used methods for the cyclopropanation of simple olefins. Indeed, it is this method that Simmons and Smith used in their seminal publications, whereby they favoured the use of a zinc-copper couple.7'8 While their procedure involved heating a mixture of zinc dust and cupric oxide under a hydrogen atmosphere, this has been replaced by more convenient methods, including treatment of zinc powder with a cupric sulphate solution, treatment of zinc dust with a hot solution of cupric acetate in acetic acid, and mixing zinc dust with cuprous chloride under nitrogen.5 While these procedures have remained the mainstay of Simmons-Smith reactions over the past 25 years, related activation procedures exist, including the use of the zinc-silver couple.50 Despite the wide use of these procedures, irreproducible results are occasionally observed as a result of inconsistencies in forming the active zinc reagent. The other major disadvantage is that an ethereal solvent must be used for the activation process. Under such conditions the electrophilicity of the active zinc reagent is reduced, thus lowering its reactivity. Also, the majority of stereoselective Simmons-Smith reactions (see 1.4.4.3) require noncomplexing solvents to maximize stereoselectivity and so this method is not applicable.5 Class 2, alkyl group exchange Many of the downsides highlighted above were overcome by Furukawa and co-workers, who showed that a mixture of diethyl zinc and diiodomethane gives very reproducible results in generating the active reagent via alkyl group exchange.12 This procedure can be performed in non-coordinating solvent and thus is highly useful in stereoselective Simmons-Smith reactions (see 1.4.4.3). Subsequent work by Denmark and co-workers showed that in certain cases (especially for deactivated olefin substrates) it is advantageous to use bis(chloromethyl zinc as the active species, which is prepared from ZnEt2 and CH2ICI.51 Another underused method for preparing IZnCH2l involves the treatment of EtZnl with CH2I2.52 This method is particularly

Name Reactions Carbocyclic Ring Formations

38

useful on large scale because it avoids the use of pyrophoric Et2Zn. More recently, several other highly effective reagents have been reported for use in Simmons-Smith reagents, prepared via alkyl group exchange. Iodomethylzinc trifluoroacetate, prepared by mixing tifluoroacetic acid, diethyl zinc and diiodomethane is a very effective cyclopropanating reagent. Likewise, substituted iodomethylzinc aryloxides (for example 2,4,6-Cl3C6H20ZnCH2l) are very useful in the cyclopropanation of unfunctionalized olefins.54 Class 3, insertion of a diazoalkane into a zinc iodide bond Despite the fact that diazoalkane derived reagents were some of the first examined by Wittig and co-workers for the Simmons-Smith reaction,10 and the huge growth of diazo compound usage in other cyclopropanating methods, this reagent preparation procedure has only appeared sporadically in the literature for Simmons-Smith reactions. A very recent publication by Charette and co-workers may draw more attention to this method however.55 In an attempt to enantioselectively prepare aryl-substituted cyclopropanes, they showed that exposure of allylic alcohol substrates to a reagent formed from EtZnl, phenyldiazomethane, and their chiral ligand (55, see 1.4.4.3.2) resulted in the formation of the product in good yield and excellent diastereoselectivity and enantioselectivity.55 Of particular note, however, was the fact that consideration of the mechanism led the team to consider the possibility of a Simmons-Smith reaction catalytic in zinc. Indeed, they found that exposure of nonracemic chiral substrate 66 to just 5 mol % of zinc iodide along with stoichiometric NaH and excess phenyldiazomethane, resulted in the formation of product 67 in excellent yield, good diastereoselectivity and excellent enantioselectivity. This is the first example of an asymmetric cyclopropanation catalytic in a zinc salt. Me

i) Znl2 (5 mol%) ii) NaH (1 equiv)

OH Me-7"^

66

Ph^N

(2 5equiv)

-

CH2CI2, -20 °C

95% yield 4:1 d.r., 99% e.e.

Mechanistically the reaction is hypothesized to proceed via reaction of zinc iodide with phenyldiazomethane to form a zinc carbenoid, which in turn reacts with the sodium alkoxide formed in situ (from the alcohol and

Chapter 1 Three-Membered Carbocycles

39

NaH) to produce the cyclopropanated product, regenerating the zinc iodide salt.55 PfT^N 2

ONa

1.4.5.2

Other Metal Carbenoids: Samarium and Aluminium Me

Me

68 69 : 70 : 71 Et2Zn, CH2I2 74 2 :3 /BU3AI, CH2I2 1 76:4 Sm(Hg), ICH2CI 98 : 0 :0 Et2Zn, IZnCH2l 91 : 2 :3

In addition to zinc-based carbenoids, other potential active agents of the general structure "MCH2X" have been proposed. For example in 1985, Yamamoto and co-workers described the preparation and use of aluminium based carbenoids (R2AICH2I).14 Subsequently, in 1987 Molander and coworkers reported the use of a samarium/mercury amalgam and CH2I2 to generate samarium carbenoids.13 While these species are less well characterized than their zinc counterparts and their use has not been so

Name Reactions Carbocyclic Ring Formations

40

widely adopted, they do show some interesting chemoselectivity. This is clearly demonstrated in the cyclopropanation of geraniol (68). The allylic alcohol functionality is selectively cyclopropanated (see 69) in the presence of the isolated olefin for the zinc and samarium derived reagents, whereas it is the terminal double bond that selectively reacts (see 70) in the presence of the aluminium carbenoid.6 It is interesting that if the alcohol is protected as a benzyl ether, all three reagents cyclopropanate the allylic position. Other interesting selectivities are observed in the stereoselective cyclopropanation of acyclic chiral nonracemic allylic alcohols. For example, cyclopropanation of substrate 72 gave the syn isomer 73 as the major product in the case of the zinc carbenoid and the anti isomer 74 in the case of the samarium reagent.6 Me

Sm(Hg), CH2I2 v a/

l i

Me^^^

THF

R

s H~v Sm~C; Q 75

I

H

More reactive conformer with samamarium oxonium

72

^Me 0H

R

ZnEt2, CH2I2 CH2CI2

' 0 / / C L p. H*^^3« H Q7 n R

., Me.

■^r /x^Me OH 73

More reactive conformer with zincalkoxide

76

As stated in section 1.4.4.2, a variety of factors, including substrate ratios, solvent, and stereoelectronic effects, play important roles in the selectivity of these reactions, however, in general, the stereochemical outcome can be qualitatively predicted by assuming an oxygen groupassisted delivery of the methylene group from a conformation that minimizes A(l,3) strain.6 The fact that the samarium reagent gives the anti isomer as the major product for substrate 72 suggests a different conformer is involved in the cyclopropanation reaction. One possibility is that deprotonation of the alcohol does not occur with the less basic samarium reagent, and the most reactive conformer is, therefore, the one in which the C-0(H)Sm is orthogonal to the π system (see 75) to maximize the nucleophilicity of the alkene.6 Delivery of the methylene group from the face away from the alkyl group would then lead to the anti isomer. This is in contrast to the proposed favoured conformer of the zinc alkoxide (see 76).

Chapter 1 Three-Membered Carbocycles

1.4.6 1.4.6.1

41

Experimental Standard conditions O Zn/Cu CH2I2, Et20 reflux

78

Bicyclo [4.1.0] heptan-2-one (78)56 Cupric acetate monohydrate (0.16 g, 0.8 mmol) was dissolved in hot glacial acetic acid (5 mL). Zinc powder (2.8 g, 42.8 mmol) was added to this stirred solution, and after 30-60 s the green colouration disappeared and metallic red copper was deposited on the zinc. The supernatant liquid was decanted and replaced by fresh acetic acid (5 mL). The suspension was stirred, and then the supernatant liquid was once again decanted and replaced by Et20 (10 mL). The couple was washed in the same fashion with Et20 (3 χ 10 mL). Finally, the couple was covered with Et20 (20 mL). A few drops of CH2I2 was added, and an exothermic reaction occurred. A mixture of cyclohexen-2one (77, 0.96 g, 0.01 mol) and CH2I2 (7.5 g, 28 mmol) was then added dropwise, inducing a gentle reflux for 30 min. to 1 h. The mixture was then heated to reflux for 36 hours, during which time a white precipitate appeared. After cooling, H2O (2 mL) was added dropwise, and the mixture was separated by centrifugation. The ether phase was decanted and washed with 10% aqueous HC1 and then three times with H2O. The solution was dried over Na2SC>4, filtered, and the solvent removed in vacuo. This gave bicyclo[4.1.0]heptan-2-one (78, 1.0 g, 90%) as a colorless liquid. 1.4.6.2

Furukawa modification OH

EtZnCH2l (5 equiv) CH2CI2, 0 °C

OH /

Ph f>"^ 80

(a/?,//?,2i?)-a-Methyl-2-phenylcyclopropanemethanol(80) 29 To a solution of alcohol 79 (296 mg, 2.0 mmol) in anhydrous CH2CI2 (20 mL) at -10 °C was added dropwise diethylzinc (1.0 mL, 10 mmol) followed by CH2I2 (810 μ ί , 10 mmol). The mixture was then allowed to warm to

Name Reactions Carbocyclic Ring Formations

42

room temperature over 3 h. Saturated aqueous NH4C1 (10 mL) was added, and the mixture diluted with ΕΪ2Ο (80 mL) and 10% aqueous HC1 (10 mL). The organic layer was successively washed with saturated aqueous Na2SC>3 (20 mL), saturated aqueous NaHCCh (20 mL), and brine (20 mL). The organic layer was dried over anhydrous MgS04, and filtered; the solvent was removed in vacuo. Silica gel chromatography (EtOAc:hexane, 15:85) gave the syn product 80 (280 mg, 86%) as the major isomer. The less polar anti isomer (40 mg, 12%) was also isolated. 1.4.6.3

Asymmetric Simmons-Smith Using the Charette Auxiliary Me2NOC

i)

\

Ph^^^^OH 59

xCONMe2

VÌ

O s /O

55

B

(1.2equiv)

Bu CH2CI2 Zn(CH2l)2.DME (2 equiv) CH2CI2 ii) H 2 0 2 , NaOH

Ph-^^OH 62

(+)-(/S,2S)-2-Phenylcyclopropanemethanol(62)57 To a solution of dry DME (1.60 mL, 14.0 mmol) in anhydrous CH2C12 (45 mL) cooled at -10 °C (internal temperature) was added diethylzinc (1.50 mL, 14.9 mmol). Then to this mixture was added CH2I2 (2.40 mL, 29.8 mmol) over 15-20 min while maintaining an internal temperature between -8 and 12 °C. After the addition, the resulting clear solution was stirred for an additional 10 min at -10 °C. A solution of dioxaborolane 55 (2.41 g, 8.94 mmol) in anhydrous CH2CI2 (10 mL) was then added via cannula over 5 min, followed by immediate addition of cinnamyl alcohol (59, 1.00 g, 7.45 mmol) in anhydrous CH2CI2 (10 mL) via cannula over a further 5 min, maintaining the internal temperature below -5 °C. The mixture was then allowed to warm to room temperature and stirred for 8 hours at this temperature. The reaction was quenched with saturated aqueous NH4CI (10 mL) and 10% aqueous HC1 solution (10 mL). The mixture was diluted with Et20 (60 mL), and the phases were separated. The reaction flask was further washed with Et20 (15 mL) and 10% aqueous HC1 solution, and these washings were combined with the extracts. The aqueous layer was further extracted with Et20 (20 mL). A solution of 2 N aqueous NaOH (60 mL) and 30% aqueous H2O2 (10 mL) was added in one portion to the combined organic extracts. The biphasic mixture was stirred vigorously for 5 min. The two layers were the separated, and the organic layer was washed successively with 10% aqueous HC1 solution (50 mL), saturated aqueous Na2SC>3 (50 mL), saturated aqueous NaHCCh (50

Chapter 1 Three-Membered Carbocycles

43

mL), and brine (50 mL). The organic layer was dried over anhydrous MgSC>4, and filtered; the solvent removed in vacuo. Further drying of the product in vacuo was performed overnight to remove residual «-butanol from the oxidative workup. The product 62 was purified by Kugelrohr distillation (90 °C, 0.8 mm Hg) to after alcohol 62 (1.05 g, 95%, 94% ee. as determined by GC analysis of a chiral nonracemic trifluoroacetate ester derivative) as a colorless oil. 1.4.7 References 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18. 19. 20. 21. 22. 23. 24. 25. 26. 27. 28. 29. 30. 31. 32. 33. 34. 35.

[R] Simmons, H. E.; Cairns, T. L.; Vladuchick, S. A.; Hoiness, C. M. Org. React. 1973, 20, 1-131. [R] Helquist, P. M. In Comprehensive Organic Synthesis; Vol. 4, Trost, B. M, Fleming, I., Eds.; Pergamon Press: Oxford, 1991; pp 951-998. [R] Charette, A. B. Organozinc Reagents 1999, 263-285. [R] Boche, G.; Lohrenz, J. C. W. Chem. Rev. 2001, 101, 697-756. [R] Charette, A. B.; Beauchemin, A. Org. React. 2001, 58, 1^15. [R] Lebel, H.; Marcoux, J.-F.; Molinaro, C; Charette, A. B. Chem. Rev. 2003, 103, 9771050. Simmons, H. E.; Smith, R. D. J. Am. Chem. Soc. 1958, 80, 5323-5324. Simmons, H. E.; Smith, R. D. J. Am. Chem. Soc. 1959, 81, 4256^1264. Emschwiller, G. Compi, rend. 1929,188, 1555-1557. Huisgen, R. Angew, Chem. 1955, 67,439-463. Doering, W. von E.; Hoffmann, A. K. J. Am. Chem. Soc. 1954, 76, 6162-6165. Furukawa, J.; Kawabata, N.; Nishimura, J. Tetrahedron Lett. 1966, 3353-3354. Molander, G. A.; Etter, J. B. J. Org. Chem. 1987, 52, 3942-3944. Maruoka, K.; Fukutani, Y.; Yamamoto, H. J. Org. Chem. 1985, 50, 4412^4414. Charette, A. B.; Juteau, H. J. Am. Chem. Soc. 1994,116, 2651-2652. Wittig, G.; Schwarzenbach, K. Angew. Chem. 1959, 71, 652-652. Charette, A. B.; Marcoux, J.-F. J. Am. Chem. Soc. 1996,118,4539^1549. Denmark, S. E.; O'Connor, S. P. J. Org. Chem. 1997, 62, 3390-3401 and references therein. Nakamura, E.; Hirai, A.; Nakamura, M. J. Am. Chem. Soc. 1998,120, 5844-5845. Morrison, V.; Barnier, J. P.; Blanco, L. Tetrahedron 1998, 54, 7749-7764. Yong, W.; Vandewalle, M. Synlett 1996, 911-912. Taber, D. F.; Nakajima, K.; Xu, M.; Reingold, A. L. J. Org. Chem. 2002, 67,4501-4504. Winkler,J. D.; Bhattacharya, S. K.; Batey, R. A. Tetrahedron Lett. 1996, 37, 8069-8072. Winstein, S.; Sonnenberg, J.; De Vries, L. J. Am. Chem. Soc. 1959, 81, 6523-6524. Corey, E. J.; Virgil, S. C. J. Am. Chem. Soc. 1990, 112, 6429-6431. Russ, P.; Ezzitouni, A.; Marquez, V. E. Tetrahedron Lett. 1997, 38, 723-726. Paquette, L. A.; Wang, T.-Z.; Pinard, E. J. Am. Chem. Soc. 1995, 117, 1455-1456. Ratier, M.; Castaing, M.; Godet, J.-Y.; Pereyre, M. J. Chem. Res. (M) 1978, 2309-2318. Charette, A. B.; Lebel, H. J. Org. Chem. 1995, 60, 2966-2967 Takemoto, Y.; Babà, Y.; Saha, G.; Nakao, S.; Iwata, C; Tanaka, T.; Ibuka, T. Tetrahedron Lett. 2000, 41, 3653-3656. Babà, Y.; Saha, G.; Nakao, S.; Iwata, C; Tanaka, T.; Ibuka, T.; Ohishi, H.; Takemoto, Y. J. Org. Chem. 2001, 66, 81-88. Onoda, T.; Shirai, R.; Koiso, Y.; Iwasaki, S. Tetrahedron Lett. 1996, 37,4397-4400. Barrett, A. G. M.; Kasdorf, K.; Williams, D. J. J. Chem. Soc, Chem. Commun. 1994, 17811782. Barrett, A. G. M.; Doubleday, W. W.; Kasdorf, K.; Tustin, G. J. /. Org. Chem. 1996, 61, 3280-3288. Panek, J. S.; Garbacelo, R. M.; Jain, N. F. Tetrahedron Lett. 1994, 35, 6453-6456.

44 36. 37. 38. 39. 40. 41. 42. 43. 44. 45. 46. 47. 48. 49. 50. 51. 52. 53. 54. 55. 56. 57.

Name Reactions Carbocyclic Ring Formations (a) Molander, G. A.; Etter, J. B. J. Org. Chem. 1989, 54, 3525-3532. (b) Kawabata, N.; Nakagawa, T.; Nakao, T.; Yamashita, S. J. Org. Chem. 1977, 42, 3031-3035. (c) Friedrich, E. C; Biresaw, G. J. Org. Chem. 1982, 47, 2426-2429. Momose, T.; Nishio, T.; Kirihara, M. Tetrahedron Lett. 1996, 37,4987^1990. Charette, A. B.; Coté, B.; Marcoux, J. F. J. Am. Chem. Soc. 1991, 113, 8166-8167. Charette, A. B.; Marcoux, J.-F. Tetrahedron Lett. 1993, 34, 7157-7160. Mash, E. A.; Nelson, K. A. Tetrahedron 1987, 43,679-692. Sawada, S.; Takehana, K.; Inouye, Y. J. Org. Chem. 1968, 33, 1767-1770. Ukaji, Y.; Nishimura, M.; Fujisawa, T. Chem. Lett. 1992, 61-64. Liu, P.; Jacobsen, E. N. J. Am. Chem. Soc. 2001,123, 10772-10773. Kitajima, H.; Aoki, Y.; Ito, K.; Katsuki, T. Chem. Lett. 1995, 1113-1114. Long, J.; Yuan, Y.; Shi, Y. J. Am. Chem. Soc. 2003,125, 13632-13633. Takahashi, H.; Yoshioka, M.; Ohno, M.; Kobayashi, S. Tetrahedron Lett. 1992, 33, 25752578. Charette, A. B.; Brochu, C. J. Am. Chem. Soc. 1995,117, 11367-11368. Lacasse, M.-C; Poulard, C; Charette, A. B. J. Am. Chem. Soc. 2005, 127, 12440-12441. Voituriez, A.; Charette, A. B.; Adv. Synth. Catal. 2006, 348, 2363-2370. Denis, J. M.; Girard, C; Conia, J. M. Synthesis 1972, 549-551. Denmark, S. E.; Edwards, J. P. J. Org. Chem. 1991, 56, 6974-6981. Sawada, S.; Inouye, Y. Bull. Chem. Soc. Jpn. 1969, 42, 2669-2672. Yang, Z.; Lorenz, J. C; Shi, Y. Tetrahedron Lett. 1998, 39, 8621-8624. Charette, A. B.; Francoeur, S.; Martel, J.; Wilb, N. Angew. Chem., Int. Ed. 2000, 39, 45394542. Goudreau, S.; Charette, A. B. J. Am. Chem. Soc. 2009,131, 15633-15635. Limasset, J.-C; Amice, P.; Conia, J.-M. Bull. Soc. Chim. Fr. 1969, 3981-3990. Charette, A. B.; Juteau, H.; Lebel, H.; Molinaro, C. J. Am. Chem. Soc. 1998, 120, 1194311952.

Name Reactions for CarbocycUc Ring Formations Edited by Jie Jack Li Copynght © 2010 John Wiley & Sons, Inc.

Chapter 2 2.1

F o u r - M e m b e r e d Carbocycles

Staudinger K e t e n e - I m i n e Cycloaddition

Stephen W. Wright 2.1.1

Description c

N'Rs

+ Ri

R2

R3

R4

V"

Ri

| R4

R2 R3

The Staudinger ketene cycloaddition is the nonphotochemical [2 + 2] cycloaddition of a ketene and an imine to form a β-lactam. Related ketene cycloaddition reactions include the cycloaddition of a keten with an olefin to afford a cyclobutanone, with a carbonyl to give a β-lactone, and with carbodiimides to form 4-imino ß-lactams. 2.1.2

Historical Perspective

Professor Hermann Staudinger first reported the reaction in 1907, as part of an overall study on the chemistry of ketenes carried out at the University of Strassburg.1 His discovery remained largely overlooked until the emergence of penicillin and other ß-lactams as antibiotics during World War II. Since then, other classes of ß-lactam antibiotics have been developed, and the ßlactams are still widely used to treat infection. After over 100 years, this general reaction yielding ß-lactams remains one of the key methods for the synthesis of these strained heterocycles,3 which remain important in both medicinal and synthetic chemistry. 2.1.3

Mechanism

The mechanism of the Staudinger ketene imine cycloaddition reaction has been the subject of much debate and has recently been reviewed.5 The mechanism has been studied both computationally and experimentally.6 Experimental evidence gathered on solution phase reactions supports a twostep mechanism, in which addition of the imine nitrogen to the ketene carbonyl group occurs to generate an intermediate zwitterion. Subsequent cyclization of the zwitterion results in formation of the key C3-C4 σ-bond.

46

Name Reactions for Carbocyclic Ring Formations

\i

N Ri

F*2

—

Ri

R4

.Rs

-R4 R2 R3

R4

R2 R3

2

1

-N

4

3

The existence of the zwitterionic intermediates has been inferred from the results of trapping experiments and by direct observation of zwitterionic intermediates that are unable to complete the cyclization to a ß-lactam. Generation of the zwitterion 7 from ketene 5 and imine 6, followed by in situ trapping with sulfur dioxide, afforded the thiazolidine-4-one 1,1-dioxide 8.7 Similarly, reaction of the formamidate 10 with ketene 9 generated in situ by pyro lysis of the acylal afforded the formamide diethylacetal 12 upon trapping with ethanol, which suggests the intermediacy of the zwitterion 11 in this reaction pathway.8

N

Pri

CH 3

J

Ph

-Ph

+ .Ph

liquid S 0 2 - 7 8 °C

-N Ph-

CH 3

5

N C N

9

reflux

EtO

10

- 7 8 °C

Phs

N

CH 3 Plr-s Ph O O

8

7

EtOH Cl

LL Ph

liquid S 0 2

CI

CN

I

OEt 11

CN

AoEt U t l

EtO

12

Direct observation of zwitterionic intermediates has been made by the addition of azomethine heterocycles, such as pyridine to ketenes.9 In these cases, the cyclization of the zwitterion to a ß-lactam is energetically unfavorable because of the loss of aromaticity of the pyridine ring that would result. >50K

Chapter 2 Four-Membered Carbocycles

47

The long-standing observation that the presence of electron-donating groups on the imine facilitate the addition of the imine to the ketene while electron-withdrawing groups retard the reaction is consistent with the nucleophilic attack shown above.10 The cyclization step of the Staudinger reaction has been the subject of much study. It is has been generally thought that the ring closure step of the Staudinger reaction is an electrocyclic process, due to its obvious similarity to the well-studied cyclobutene system. The zwitterionic intermediate of the Staudinger reaction is regarded as a 47i-electron system and has been believed to obey the Woodward-Hoffmann rules and undergo a conrotatory ring closure. However, when monosubstituted ketenes are allowed to react with aldimines, the cis/trans ratio of the products obtained have been found to vary in rather unpredictable ways. For example, the electron-donating or electron-withdrawing nature of the ketene substituent has significant effects that are difficult to explain if the ring closure is an electrocyclic reaction.6 In addition, it has been shown that, unlike substituted 1,3-butadienes, the zwitterionic intermediates in photochemical Staudinger reactions do not undergo disrotatory ring closure as expected by application of the Woodward-Hoffmann rules.11 Recently, evidence has been developed to provide a general explanation for the various stereochemical outcomes of Staudinger reactions in which the ring closure step occurs as an intramolecular nucleophilic addition of the enolate to the iminium ion.12 N' R s Rf

R2

*3

«4

^)

+.,R5

VN)

R2R3

OvX

,R5

VN

R2R3

R4

2.1.4 Stereochemical Outcome The reaction of a monosubstituted ketene with an aldimine produces two new stereocenters, C3 and C4, in the ß-lactam ring. The substituents on these two carbon atoms may therefore be eis or trans to each other, and the reaction of any particular pair of ketene and imine may afford the eis ß-lactam, the ira«s-ß-lactam, or a mixture of the two. The importance of ß-lactams as antibacterial agents has resulted in extensive effort to understand the diastereoselectivity of the Staudinger reaction.13 The two-step nature of the reaction pathway has made the interpretation of experimental results more difficult and increased the number of possible contributing factors. The earliest hypothesis was the simplest; that the stereochemical outcome of the Staudinger reaction was determined by the Z or E

Name Reactions for Carbocyclic Ring Formations

48

configuration of the aldimine.14 Z-Aldimines would be expected to lead to toms-ß-lactam products while .E-aldimines would lead to c/s-ß-lactams.

Ri

R

H

1

7

+

H

i

+ ,R 3 N

R3

RH

^H

A

H

VN

H Ro

O, Rr

R2

+ ,R 3 -N

Ά

CL

R3

RÌ

H H

However, very few acyclic aldimines exist in the Z-conformation; therefore, the aldimine geometry cannot provide a complete explanation for the stereochemical outcome of the Staudinger reaction. Another possibility is that the initial addition of the aldimine to the ketene determines the product stereochemistry. When a monosubstituted ketene is treated with an aldimine, the attack of the aldimine may occur from the less-hindered side of the ketene bearing the smaller substituent, most often H (exo attack), or from the side of the ketene bearing the larger substituent (endo attack). According to this model, exo attack would be expected to lead to a c«-ß-lactam product, whereas endo attack would lead to the /ra«s-ß-lactam.15 ,R*

-H

R,

H

exo

VN-R3

"rff-H H R 2

-Ά Q.

,R 3

Ri

H'

One would expect that the aldimine would add to the less-hindered face of the ketene. Computational studies support this conclusion, showing that exo attack leads to lower energy transition states. Further proof that exo attack is the exclusive pathway of aldimine addition has been developed using cyclic Z-imines substituted with various electron-donating and electron-withdrawing substituents.6

Chapter 2 Four-Membered Carbocycles

49

N=

These afforded exclusively the irarcs-ß-lactams in practically quantitative yields, indicating that the aldimine approaches exclusively from the less-hindered side of the ketene, and further that the electronic nature of the aldimine does not influence the direction of aldimine attack. The third possibility is that isomerization of the aldiminium group in the intermediate zwitterion may occur at a rate that is competitive with the direct closure of the ß-lactam ring. If direct ring closure occurs at a rate significantly greater than that of aldimine isomerisation in the zwitterion, then the c/s-ß-lactam will be formed. However, if the aldimine isomerizes at a rate greater than that of cyclization, then the trans-ß-lactam may be formed. Isomerization of the aldimine would be expected to relieve steric crowding in the cyclization transition state; therefore, it might be expected that the zwitterion may favor isomerization to the Z-aldimine, in which the aldimine substituent is moved away from the ketene substituent. ring closure

exo Ri

^Η

H

-H

H-H

—H

Ri R2

,R 3

RÌ

H R2

-N

Jt

Ck

ring closure

R3

—- A 0 χ

"N—N

R-i

R2

The possibility of aldimine isomerization before cyclization is consistent with experimental observation when the cyclization is viewed as occurring by nucleophilic attack of the ketene enolate on the aldiminium ion in the zwitterionic intermediate. The effects of electron-donating and electron-withdrawing substituents in the ketene and aldimine as well as steric effects may be understood in terms of this model. Thus the stereochemical outcome of the Staudinger reaction is determined by the competition between direct ring closure of the zwitterion and isomerization of the aldimine.

Name Reactions for Carbocyclic Ring Formations

50

Further studies into the stereochemical outcome of the Staudinger reaction continue to generate new information.12 The selection of experimental conditions can influence the stereochemical outcome of the Staudinger reaction as well, further complicating matters. This can be especially important when the ketene is generated in situ, as is often the case. Many different experimental factors, such as reaction temperature, solvent,16 and the presence of potential auxiliary nucleophiles (particularly the base used to generate a ketene from an acid chloride 7 and the by-product chloride ion18) or electrophiles (such as metal ions or excess acid chloride) may affect the ratio of eis- to trans-$lactam obtained in any particular experiment. Even the order of addition of reagents has been shown to affect the stereochemical outcome. For example, in the example shown below, the addition of the acid chloride to a mixture of aldimine and triethylamine afforded predominantly the c/'s-ß-lactam {eis/trans = 3:1). However, the addition of a mixture of the aldimine and triethylamine to the acid chloride gave the reverse stereochemical outcome, favoring the formation of the /ra«s-ß-lactam {cis/trans = 1:3).'

N3

T

♦ Ι ^ p h

^

H

CH2C,2,0°C 35-650/0

VN

> - <

or p h

VN

^

Ph

2.1.5 Periselectivity The reaction of a ketene with an α,β-unsaturated imine may be expected to afford either a ß-lactam, resulting from [2 + 2] addition, or a δ-lactam, resulting from [4 + 2] addition.

R2

The formation of both types of products has been observed experimentally.20 While the influence of steric and electronic effects on the outcome of the reaction have been analyzed, the reaction of a ketene with an α,β-unsaturated imine still proceeds by the two-step mechanism and the

Chapter 2 Four-Membered Carbocycles

51

periselectivity is determined in the second step. Thus it should be recognized that the periselectivity of any particular reaction may be influenced by the selection of reaction conditions and the presence of additional reagents or reaction by-products, as noted previously. 2.1.6

Variations and Improvements

The oldest method for the formation of a ketene, used by Staudinger in his studies on diphenylketene, is the reduction of an a-haloacyl halide with activated zinc.21 Most often, the ketene components used in the Staudinger reaction are usually produced by either of two ways: the elimination of an acyl chloride (or less frequently another activated carboxyl derivative) in the presence of a base,22 or the Wolff rearrangement of a-diazocarbonyl compounds.23 The ketene is usually generated in situ in the presence of the imine; however, if the ketene is stable enough, it may be prepared separately and then introduced into reaction with the imine. Other methods to produce ketenes have been used less often in the Staudinger reaction due to incompatibility with the imine component or ß-lactam product or due to the harsh conditions required, such as the high temperatures employed in the pyrolysis of acid anhydrides or ketone acylals. The ease of preparation of ketenes and their use in the Staudinger reaction depends on their reactivity. Most ketenes dimerize readily, are hydrolyzed easily, and are sensitive to oxidation by oxygen. However, some ketenes, such as trimethylsilylketene and diphenylketene, may be isolated as pure compounds.24 The elimination of an acyl chloride by a tertiary amine base has been widely used to generate the ketene component in situ due to its convenience and the ready availability of the starting acyl chlorides. The tertiary amine must be a nucleophilic tertiary amine, and triethylamine is generally used. The tertiary amine forms an intermediate acylammonium salt that undergoes decomposition to the ketene.2 O^CI

Et3N

X

_

J./\

cr

EtsN

Et3N«HCI

Despite the method's convenience, the presence of the acyl chloride, the tertiary amine, and the tertiary amine hydrochloride may all introduce further complications.26 The Wolff rearrangement of a-diazocarbonyl compounds offers perhaps the "cleanest" means of generating a ketene in situ without the

52

Name Reactions for Carbocyclic Ring Formations

presence of additional reactants or by-products. The rearrangement may be induced by photolysis or heat.27 The ready availability of oc-diazocarbonyl compounds by diazo transfer from sulfonyl azide reagents to ketone and ester enolates,28 and the ease with which the Wolff rearrangement may be induced make this a valuable method for the generation of the ketene component. heat6 or

-.

0

N

''

2

— -

Rh 2 (OAc) 4 28

c

S


^ O +

N,

Other methods for ketene generation that are occasionally used are conceptually similar to the elimination of acyl chlorides but use different carboxyl activating groups. Activation of a carboxylic acid by Mukaiyama's reagent, for example, followed by treatment with triethylamine to generate a ketene in situ, has been used on occasion.29 A very mild method for ketene formation involves treatment of the carboxylic acid with triphenylphosphine and carbon tetrabromide in the presence of the imine.30 The photolysis of metal-carbene complexes, particularly chromium carbonyl carbenes, has been used but this necessarily involves more effort in the preparation of the necessary ketene precursor.31 2.1.7

Enantioselective methods

Until recently, attempts to conduct the Staudinger reaction in such a way as to favor the formation of one eis (or much less frequently, one trans diastereomer) over the other possible eis or trans diastereomer have made use of a fixed chiral center in one of the reactants to influence the stereochemical outcome of the reaction. Thus asymmetric induction may be brought about by the presence of one or more chiral centers on the imine, or the ketene, or both. Further, a chiral imine may be derived either from a chiral aldehyde and an achiral amine or from a chiral amine and an achiral aldehyde. The asymmetric synthesis of ß-lactams using the Staudinger reaction has been recently reviewed.5 The use of a chiral aldehyde to generate a chiral imine is somewhat more difficult than it might first appear. The chiral center should be close to the aldehyde carbonyl, but these are notorious for their facile enolization. Further, it is imperative that the derived imine does not also enolize to form the corresponding enamine. In general, aldehydes substituted with ocnitrogen or oc-oxygen substituents have been found suitable, while successful applications of α-alkyl aldehydes have been less common. Aldehydes with chiral α-nitrogen substituents are readily derived from oc-amino acids, and N-

Chapter 2 Four-Membered Carbocycles

53

BOC imines, derived from N-BOC α-amino aldehydes or Garner's aldehyde32 often afford ß-lactams with high diastereoselectivity.33

O^CI

J^> cf^^

PhtN

υ

Ci

^ ^ y

ph

·

.r.

„OMe Et 3 N,CH 2 CI 2

d?Ì?, eC . to , rt

73%, single diastereomer

Boc

PhtNù Ü H

H

Aldehydes with chiral α-alkoxy substituents may be derived from ochydroxy acids, sugars,34 and other chiral pool fragments such as sodium erythorbate.35 Highly diastereoselective Staudinger reactions have been reported with these imines as well. Glyceraldehyde imines have also been used to provide ß-lactam products with high diastereoselectivity, as shown below. Cyclic imines, such as enantiomerically pure dihydropyrazinones and benzoxazepines,38 have been used in highly enantioselective Staudinger reactions.

c.OMe

fr


j

*O

N-^^ : Ö

Et3N CH2CI2, rt 68%, > 99% ee

In contrast, imines derived from alkyl aldehydes generally perform poorly in the Staudinger reaction under most circumstances, and examples of their successful use to cause asymmetric induction in the Staudinger reaction are unusual. However, enolization may be suppressed by appropriate design of the aldehyde, such as the example shown in which the formation of an enol or an enamine is disfavored.39

Name Reactions for Carbocyclic Ring Formations OMe

°
Et,N

+

J

PhtN

CH2CI2

-78 °C, 98% 9:1

.OMe

PhtN

.OMe

PhtN

The use of a chiral amine to generate a chiral imine is obviously attractive. Chiral amines (and amino alcohols) are readily available, and they have been used successfully in numerous enantioselective methodologies. However, imines derived from chiral amines and achiral aldehydes have generally afforded disappointing levels of asymmetric induction.40 This is perhaps to be expected because the imine N-substituent is relatively remote from the C3 and C4 substituents in the assembled transition state. For example, modest diastereoselectivity was observed with the use of the imine 13, which is derived from a commercially available aminodiol.408

°^J

Ϊ

P r u .^OTBS

CI

1)Et 3 N, CH2CI2 -40 °C to rt

.OTBS

2) 5% aq HF, MeCN, rt 52%, 8:1

PhtN

Ph

13 Più

PhtN

„OH

Pru ,>OH

PhtN

Chapter 2 Four-Membered Carbocycles

55

More selective examples have used imines derived from amino acids, including phenylalanine41 and, more generally useful, O-protected threonine 42

esters.

o

;

ci

) AcO

+

fT^T

Jj

Et

I

"SiPh2f-Bu

3"

CH 2 CI 2 ,^0X

ητ vex 0 ^ 0

0^,0

o AcO

Ph

SiPh2i-Bu Αοΰ 65%, 19:1

'Ph

SiPh2f-Bu

By contrast, very high diastereoselectivities have been observed by the use of chiral hydrazones prepared from the C2 symmetric hydrazine 2,5dimethyl-pyrrolidin-1-ylamine.4 The asymmetric induction comes at a price, however: The hydrazine is not commercially available, and it cannot be recovered as such following oxidative cleavage from the ß-lactam. More readily available, and therefore more expendable, hydrazines are SAMP analogs derived from L-proline.44

O^/CI BnCT Bnu

+ _

V-Λ Et3N N y »► a ,N^y 11' toluene, 100 °C ^ N II I 1 H BnO

82% 3R4S isomer >98%cte

Chiral ketene fragments have proven to offer more general utility in the quest for enantioselective Staudinger reactions. In particular, ketenes containing the Evans oxazolidinone have proven to offer high diastereoselectivities in the synthesis of 3-amino-ß-lactams. 5 The ease of preparation of the carboxylic acid precursor, the low cost of the auxiliary, and the facile unmasking of the 3-amino group from the auxiliary all

Name Reactions for Carbocyclic Ring Formations

56

contribute to the utility of this approach. The following is an example in which the ß-lactam was obtained as a single enantiomer in good yield.45f

Ph

°^ CI T^

N

θΛ0

„s> +

s^sS^H

[I

I

Et3N

CH2CI2/toluene

-78°C, 87%

Thiazolidine-substituted ketenes derived from cysteine and other chiral aminothiols have also been used successfully to generate spiro-ßlactams with excellent diastereoselectivity and, with a large enough substituent, high enantioselectivity.46 Ketenes derived from proline have been used similarly.47 Solutions to the synthesis of ß-lactams substituted with functionality other than an amino group at C3 are less general. Carbon and oxygen substituents bearing chiral groups have been employed as potential chiral directors at the ketene 2-position, often with disappointing levels of diastereoselectivity.48 A rigid and more sterically demanding bicyclic ketene has afforded excellent diastereoselectivity {dr 7:1 to 50: l).49 Recently, ethyl L-(+)-tartrate has been used to generate a ketene with a chiral alkoxy substituent.50 Diastereoselectivity was again very modest; however this provides access to 3-keto-ß-lactams, which offer many options for further functionalization.

o The two-component nature of the Staudinger reaction suggests that double asymmetric induction may afford improved diastereoselectivity. The chiral groups may be paired in any of three ways: (1) a chiral aldehyde with a chiral amine to place two defined stereocenters on the imine, (2) an imine with a chiral jV-substituent with a chiral ketene substituent, and (3) an imine with a chiral C-substituent with a chiral ketene. Some examples of these possibilities have been reported.

Chapter 2 Four-Membered Carbocycles

57

The first pairing, that of a chiral aldehyde with a chiral amine, has been used to further develop the threonine imine method. The use of a threonine-derived imine of (5)-glyceraldehyde acetonide afforded a single diastereomer in 61% yield.51

N

VAc/rBS

The second pairing, that of an imine with a chiral JV-substituent with a chiral ketene substituent, presents an attractive synthetic design because both chiral auxiliaries may be removed subsequent to ß-lactam formation. The Evans-Sjogren chiral auxiliary on the ketene and imines derived from amino acids are clear choices for such a combination. An example is the combination of the Evans-Sjogren chiral auxiliary with an imine derived from (5)-valine, which gave a single diastereomer in excellent yield.52

Ph

l

ovci

M--^0

T

"

1

) Et3N, CH2CI2, -78 °C

2) CH2CI2, -78 °C to rt 86%, > 99% de

Ph.

The third pairing, that of an imine with a chiral C-substituent with a chiral ketene, has also been studied. Again, the Evans-Sjogren chiral auxiliary was used as the directing group on the ketene, while imines derived from (i?)-glyceraldehyde acetonide5 and lactic acid54 have been used.

Ph V

C I

b-A.b

N \

-"\

O

^j

BsN

CH2CI2

-78 °c'57%

Name Reactions for Carbocyclic Ring Formations

58

In addition, asymmetric induction from chiral centers on all three possible groups—the imine C-substituent, the imine N-substituent, and the 53 ketene—has been described.

Ph

C^XI

Et3N CH2CI2

TBS'°

*-

ru

Ph

VN l_l

-78°C,57% V N ^ T ^ 85:15 X

0"^0

°"TBS

\>^0

°"TBS

The emergence of catalytic asymmetric methods to effect the Staudinger reaction appears to have largely displaced further efforts to identify new methodology based on the use of chiral auxiliaries. These methods rely on the nucleophilic activation of the ketene to form a zwitterionic enolate, which then undergoes nucleophilic addition to the imine, followed by cyclization. While the assembly of enantiodifferentiated transition states using Lewis acid catalysis has been well developed, the use of Lewis base catalysts to accomplish the same purpose is a relatively recent development and well suited to the Staudinger reaction. The first catalytic asymmetric Staudinger reaction to be described used chiral tertiary amines 14 and 15 derived from the Cinchona alkaloids as the nucleophile to activate the ketene via zwitterion formation.55 The ketene was conveniently generated in situ from the acid chloride. Because the HC1 generated in the elimination would consume the chiral tertiary amine catalyst, a nonnucleophilic strong base (e.g., Proton Sponge) was included to remove the HC1 formed. Yields of ß-lactams were on the order of 60% in 99% ee.

Chapter 2 Four-Membered Carbocycles

59

The next catalyst to be described for the catalytic asymmetric Staudinger reaction was the planar chiral dialkylaminopyridine derivative 16.56 In this case, the ketene was prepared separately before reaction with the imine, and therefore, an auxiliary base was not necessary.

N £3 *N Fe

16 In each of these approaches, it is necessary that the imine be a relatively electrophilic N-tosyl imine. Further work by Fu showed that transß-lactams could be formed in good yields and ee, if the corresponding triflyl imines were employed.57 10% catalyst CH2CI2, rt 84%, 96:4 trans/cis 85% ee

Both of these approaches have been developed and refined further,58 although no truly general solution has yet been developed. Lectka has described less expensive bases to consume the HC1 formed during ketene generation, with sodium hydride/15-erown-5 being the most promising early candidate.59 It should be noted that diisopropylethylamine (Hunig's base) was specifically described as being unsuitable, due to competitive catalysis of the Staudinger reaction by this amine. Subsequently, conditions were found in which sodium bicarbonate performed well as the terminal base.60 Further refinements of this method include the use of enantiomerically pure cyclophane61 and indium62 cocatalysts. Recently, an anionic co-catalyst has been described that favors the formation of trans diastereomers in high ee,63 which have been difficult to access previously. Similarly, sodium bis(trimethylsilyl)amide has been used to catalyze the Staudinger reaction of relatively unreactive ketenes with imines in a nonenantioselective manner.64 Chiral ./V-heterocyclic carbenes have recently been described as nucleophilic catalysts for the Staudinger reaction. The carbenes may be

60

Name Reactions for Carbocyclic Ring Formations

conveniently prepared enantiomerically pure from either pyroglutamic acid65 or ira«i-l,2-diaminocyclohexane.66 The ketenes were generated separately from the Staudinger reaction mixture, suggesting that further improvements in convenience and reaction scope may be identified. 2.1.8

Synthetic Utility

2.1.8.1 General Utility In general, ketenes substituted with electronegative atoms such as O, N, F, or Cl, as well as those bearing by SO2 or aryl groups, perform satisfactorily in the Staudinger reaction. Alkyl ketenes remain problematic. It is not clear whether the difficulties are entirely due to the inherent reactivity alkyl ketenes, particularly monoalkyl ketenes, which dimerize within minutes at room temperature, or whether the difficulties are due at least in part to the conditions generally used to generate the ketenes in situ from the acid chlorides. Some evidence that the latter may be at least partially responsible is the successful use of alkyl ketenes generated by the Wolff rearrangement in the Staudinger reaction.67 Acetyl chloride has been used as a ketene precursor to prepare ßlactams unsubstituted at C3. 68 Unsubstituted imine fragments pose special difficulties in the Staudinger reaction. Formaldehyde imines are difficult to prepare and handle, and generally ß-lactams unsubstituted at C4 are not readily accessible. By contrast, formaldehyde hydrazones are more stable and can be used in place of the unstable imines in the Staudinger reaction to afford 4-unsubstituted ß-lactams.69 °*γα

^Ν^

A

H

H

Et3N, toluene

rt, 84%

Q.

\ .N-

J—I

BnCT

The synthesis of ß-lactams unsubstituted on nitrogen also cannot be accomplished directly due to the instability of most imines derived from ammonia. However, imines derived from 4-methoxyaniline and 4ethoxyaniline readily afford N-aryl ß-lactams; cleavage of the TV-aryl bond is accomplished by oxidation with eerie ammonium nitrate.70 ./V-Trimethylsilyl imines have also been used to provide NH ß-lactams.54

Chapter 2 Four-Membered Carbocycles

ph ° V C l T ^ / N

Pf

o A

O

I

)sr N ^ H kl

. \ ^

O

TIPS"

1) heptane, THF TMSCI, 0 °C to rt 2) Et3N, toluene

0to110°C

59%, 4:1 trans/cis

61

V Ph

A^l\f

(

1

0^0

N

^

'

H

<X

^TIPS

The catalytic enantioselective synthesis of ?ra«s-ß-lactams has also been problematic because the nucleophilic catalysts employed facilitate the cyclization reaction, which leads to cw-ß-lactam products from .E-imines. A workaround has been developed by Lectka, in which an anionic nucleophilic catalyst is used.63

10% catalyst MeO'^^^

Ts

'

toluene, 0 °C Proton Sponge 70%, 13:1 dr

// MeO'

The catalyst is a dihydro-l//-imidazol-2-yl-benzenesulfonic acid; which is used as the tetraheptylammonium salt to suppress the formation of ion pairs as much as possible.

tetraheptylammonium salt

Remarkably, both 3-keto and 3-aza ß-lactams are accessible. The 3keto ß-lactams may be prepared ultimately from diethyl tartrate.50 Conversion to the acetonide, followed by saponification and treatment with oxalyl chloride, gave the acid chloride, which was treated with triethylamine and an imine to give the spiro ß-lactam. Removal of the acetonide followed by oxidative cleavage of the diol afforded the 3-keto-ß-lactam.

Name Reactions for Carbocyclic Ring Formations

62 MeO.

OEt

O ° E t CH2CI2, rt

H^O^P

Nal04

VA

Me2CO, H20 rt, 78% overall

y/O

..I—^ O \

^

An alternate approach to 3-keto-ß-lactams involves formation of the thiazolidine-derived spiro-ß-lactam 17, followed by cleavage of the thiazolidine moiety by oxidation.71 0

sì?

,Bn

1)HCI, EtOAc, 60 °C ►

2) DMSO, CHCI3, 45 °C 72% overall

17

A. O

,Bn

3-Aza-ß-lactams may be prepared by the Staudinger reaction of a ketene with an azodicarboxylate ester under catalysis by a planar chiral nucleophile.72 Dimethyl azodicarboxylate and diethyl azodicarboxylate performed well in this reaction. Higher azodicarboxylate esters afforded lower yields and lower enantioselectivities, while an azodicarboxamide failed to undergo reaction. 2.1.8.2 Applications in synthesis The 2-azetidinone system has emerged as a useful, densely functionalized fragment that may be elaborated in a variety of different ways. Thus ßlactams have emerged as interesting synthetic intermediates, besides their obvious utility as antibacterial agents. In particular, ring opening of ßlactams has been shown to provide stereocontroUed synthesis of both a- and ß-amino acids, as well as functional group derivatives of these, such as ß-

Chapter 2 Four-Membered Carbocycles

63

amino amides, alcohols, esters, and ketones. The intense interest generated by the discovery of the antitumor agent paclitaxel spurred interest in the Staudinger reaction to generate a synthetic equivalent to the phenylpropionyl side chain fragment 18. For example, the ß-lactam 19 was appended to the paclitaxel core by acylation of the core 13-position alcohol by the ß-lactam carbonyl.73b

ov

18

tf

19

Ring opening of ß-lactams by amines affords ß-amino amides, which are fragments of interest from both a medicinal chemistry perspective and for the synthesis of natural products. Intramolecular aminolysis of a ß-lactam affords a l,4-diazepin-5-one.74

toluene reflux, 34%

^

7=^

Two recent examples of the use of the Staudinger reaction to construct key intermediates in the total synthesis of natural products are the syntheses of oseltamivir and (-)-cribrostatin.

Name Reactions for Carbocyclic Ring Formations

64

The key step in the synthesis of oseltamivir 20 was the use of the Staudinger reaction to set all three contiguous chiral centers using the chiral center of (5)-methionine to induce the required asymmetry at C3 and C4 of the ß-lactam.75 OMe

OMe /-Pr2NEt CH2CI2 -15 °C tort, 55%

Boc ^NH

η ^ Π ν ^ ί Boc

Similarly, a key strategy in an elegant synthesis of (-)-cribostatin was the use of a chiral auxiliary to fix the stereochemistry of C3 and C4 of the βlactam, which subsequently determined the stereochemical outcome of a Pictet-Spengler reaction on the aryl ether. Subsequently, the ß-lactam was used to set the stereochemistry of the pentacyclic framework of (-)cribrostatin by reduction with lithium borohydride and spontaneous cyclization.76

CI Ph Pri

OBn

OBn

ph

2.1.9 Experimental Staudinger cycloaddition using the Wolff rearrangement to generate a ketene28 Caution! Diazo compounds are presumed to be toxic and potentially explosive and, therefore, should be handled with caution in a fume hood. Although in carrying out this reaction numerous times we have never observed an explosion, we recommend that these reactions be conducted behind a safety shield.

Chapter 2 Four-Membered Carbocycles

65

./V-Benzylidene-/>-anisidine A 100 mL, three-necked, round-bottomed flask is equipped with an argon inlet adapter, rubber septum, glass stopper, and a magnetic stirring bar. The flask is charged with 45 mL of CH2C12 and 3.00 mL (0.030 mol) benzaldehyde, and then is cooled in an ice-water bath while a solution of 3.50 g (0.028 mol) p-anisidine in 5 mL CH2CI2 is added dropwise via syringe over 15 min. After 30 min, 7.5 g anhydrous magnesium sulfate is added in one portion. The ice-water bath is removed, and the reaction mixture is stirred at room temperature for 2 h. The resulting mixture is then filtered through a sintered glass funnel with the aid of two 5-mL portions of CH2CI2, and the filtrate is concentrated at reduced pressure by rotary evaporation at room temperature to afford a pale brown powder. This material is dissolved in 150 mL ethanol heated in an 80 °C water bath while 270 mL hot water is added with stirring. The resulting solution is allowed to cool to room temperature and then is cooled in an ice-water bath for 2 h. Filtration provides 5.31 g (88%) of 7V-benzylidene-/?-anisidine as brown metallic plates. ira«s-l-(4-Methoxyphenyl)-4-phenyl-3-(phenylthio)azetidin-2-one A 500-mL, three-necked, round-bottomed flask is equipped with a magnetic stirring bar, reflux condenser fitted with an argon inlet adapter, glass stopper, and 50-mL pressure-equalizing dropping funnel fitted with a glass stopper. The flask is charged with 3.50 g (0.016 mol) iV-benzylidene-p-anisidine, 200 mL CH2CI2, and 0.045 g (0.10 mmol) rhodium(II) acetate dimer, and the resulting green solution is heated at reflux while a solution of 4.43 g (0.025 mol) S-phenyl diazothioacetate in 40 mL of CH2CI2 is added via the dropping funnel over 1 h (the dropping funnel is rinsed with 2 mL CH2CI2). The reaction mixture is further heated at reflux for 5 min, then allowed to cool to room temperature. After transfer to a 500-mL, round-bottomed flask, the mixture is concentrated by rotary evaporation at reduced pressure to provide a brown oil. This material is filtered through a column of 50 g of silica gel (elution with 750 mL CH2CI2) to remove polar impurities and is concentrated under reduced pressure to afford a brown solid, which is washed on a sintered glass funnel with 10 mL ethyl acetate and then 20 mL hexane. The resulting pale yellow powder is dissolved in 40 mL ethyl acetate at 80 °C, and 400 mL hexane (pre-heated in a water bath at 80 °C) is then added in one portion. The resulting solution is allowed to cool to room temperature and then cooled further at -20 °C for 2 h to afford 5.50 g (91%) trans-l-(4methoxyphenyl)-4-phenyl-3-(phenylthio)azetidin-2-one as off-white crystals. Catalytic asymmetric Staudinger cycloaddition using benzoylquinine as nucleophilic catalyst and sodium bicarbonate as base °

66

Name Reactions for Carbocyclic Ring Formations

To a vigorously stirred solution of NaHCC^ (350 mg, 4.01 mmol), benzoylquinine (6 mg, 0.0129 mmol), and 15-crown-5 (3 mg, 0.0129 mmol) in toluene (6 mL) at -40 °C, phenylacetyl chloride 1 (20 mg, 0.129 mmol) in toluene (1 mL) at -40 °C was added dropwise, followed by oc-imino ester 2 (33 mg, 0.129 mmol) in toluene (2 mL). The reaction was allowed to stir for 5 h as it slowly warmed to room temperature. The reaction mixture was washed with 1 M HCl, extracted with CH2CI2 (3 x). The organics were combined and dried with MgSCv The solvent was removed under reduced pressure, and the crude mixture was subjected to column chromatography (15% EtOAc-hexanes) on a plug of silica gel to yield 5a (58% yield, 28 mg). 2.1.10 References 1.

2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16.

(a) Staudinger, H. Chem. Ber. 1907, 40, 1145-1148, (b) Staudinger, H. Liebigs Ann. Chem. 1907, 356, 51-123. These experiments were facilitated by the relative stability of diphenylketene (1), which was stored and handled as a solution in diethyl ether. The concentration of the ether solution could be accurately determined by titration after hydrolysis of the ketene to diphenylacetic acid with water. Staudinger believed that the structural assignment of his product as a ß-lactam was precedented by the work of Meyer (Meyer, H. Monatshefte fuer Chemie 1900, 21, 965-980), which he cited. However, Meyer's structural assignments of the cantharidine ring and its derivatives were subsequently shown to be erroneous. Kattan, J. N.; Villegas, M. V.; Quinn, J. P. Clin. Microbiol. Inf. 2008, 14, 1102-1111. (a) Palomo, C; Aizpurua, J. M.; Ganboa, I.; Oiarbide, M. Eur. J. Org. Chem. 1999, 32233235; (b) Palomo, C; Aizpurua, J. M.; Ganboa, I.; Oiarbide, M. Curr. Med. Chem. 2004, / / , 1837-1872. [R] Chemistry and Biology of ß-Lactam Antibiotics; Morin, R. B.; Gorman, M., Eds.; Academic Press: 1982; Vols. 1-3. Cossio, F. P.; Arrieta, A.; Sierra, M. A. Ace. Chem. Res. 2008, 41, 925-936. Jiao, L.; Liang, Y.; Xu, J. J. Am. Chem. Soc. 2006,128, 6060-6069. (a) de Souza Gomes, A.; Joullik, M. M. J. Heterocycl. Chem.1969, 6, 729-734; (b) Decazes, J. M.; Luche, J. L.; Kagan, H. B.; Parthasarathy, R.; Ohrt, J. T. Tetrahedron Lett. 1972, 13, 3633-3636; (c) Bellus, D. Helv. Chim. Ada 1975, 58, 2509-2511. (a) Moore, H. W.; Hernandez Jr., L.; Kunert, D. M.; Mercer, F.; Sing, A. J. Am. Chem. Soc. 1981, 103, 1769-1777; (b) Moore, H. W.; Hernandez Jr., L.; Chambers, R. J. Am. Chem. Soc. 1978,100, 2245-2247. [R] Quiao, G. H.; Andraos, J.; Wentrup, C. J. Am. Chem. Soc. 1996,118, 5634-5638. [R] Moore, J. A. In Heterocyclic Compounds with Three and Four Membered Rings, Part 1 Weissberger, A., Ed.; John Wiley & Sons: New York, 1964; pp 929-939. Liang, Y.; Jiao, L.; Zhang, S. W.; Xu, J. X. J. Org. Chem. 2005, 70, 334-337. Liang, Y.; Jiao, L.; Zhang, S. W.; Yu, Z.-X.; Xu, J. X. J. Am. Chem. Soc. 2009, 131, 15421549. See reference 12 and references cited therein, particularly references 8-10. Hegedus, L. S.; Montgomery, J.; Narukawa, Y.; Snustad, D. C. J. Am. Chem. Soc. 1991, 113, 5784-5791. (a) Brady, W. T.; Gu, Y. Q. J. Org. Chem. 1989, 54, 2838-2842; (b) Dumas, S.; Hegedus, L. S.y. Org. Chem. 1994, 59,4967^971. Palomo, C; Cossio, F. P.; Odriozola, J. M.; Oiarbide, M.; Ontoria, J. M. Tetrahedron Lett. 1989, 30,4577^1580.

Chapter 2 Four-Membered Carbocycles 17. 18. 19. 20.

21. 22. 23. 24. 25. 26. 27. 28. 29. 30. 31.

32. 33. 34.

35. 36. 37. 38. 39. 40.

41.

67

Browne, M; Burnett, D. A.; Caplen, M. A.; Chen, L. Y.; Clader, J. W.; Domalski, M.; Dugar, S.; Pushpavanam, P.; Sher, R.; Vaccaro, W.; Viziano, M.; Zhao, H. Tetrahedron Lett. 1995, 36, 2555-2558. (a) Bose, A. K.; Spiegelman, G.; Manhas, M. S. Tetrahedron Lett. 1971, 12, 31673170; (b) Arrieta, A.; Lecea, B.; Cossio, F. P. /. Org. Chem. 1998, 63, 5869-5876. See also reference 15b. Bose, A. K.; Anjaneyulu, B.; Bhattacharya, S. K.; Manhas, M. S. Tetrahedron 1967, 23, 4769^*776. (a) Brady, W. T.; Shieh, C. H. J. Org. Chem. 1983, 48, 2499-2502; (b) Moore, H. W.; Hughes, G.; Srinivasachar, K.; Fernandez, M.; Nguyen, N. V.; Schoon, D.; Tranne, A. J. Org. Chem. 1985, 50, 4231^238; (c) Lecea, B.; Arrastia, I.; Arrieta, A.; Roa, G.; Lopez, X.; Arriortua, M. I.; Ugalde, J. M.; Cossio, F. P. J. Org. Chem. 1996, 61, 3070-3079. Staudinger, H. Chem. Ber., 1905, 38, 1735-1739. [R] Ward, R. S. In The Chemistry ofKetenes, Allenes, and Related Compounds, Part 1; Patai, S., Ed.; John Wiley and Sons: New York, 1980; pp 231-232. [R] Ward, R. S. In The Chemistry ofKetenes, Allenes, and Related Compounds, Part 1; Patai, S., Ed.; John Wiley and Sons: New York, 1980; pp 227-239. (a) Pelotier, B.; Rajzmann, M.; Pons, J.-M.; Campomanes, P.; Lopez, R.; Sordo, T. L. Eur. J. Org. Chem. 2005, 2599-2606; (b) Darling, S. D. ; Kidwell, R. L. J. Org. Chem. 1968, 33, 3974-3975. Brady, W. T.; Scherubel, G. A. J. Am. Chem. Soc. 1973, 95, ΊΜΊ-Ί449. (a) Brady, W. T.; Waters, O. H. J. Org. Chem. 1967, 32, 3703-3705; (b) Brady, W. T.; Smith, L.J. Org. Chem. 1971, 36, 1637-1640. The Wolff rearrangement may also be brought about by catalysts such as rhodium, copper, or silver salts. Danheiser, R. L.; Okamoto, I.; Lawlor, M. D.; Lee, T. W. Org. Synth. Vol. 80, 160-171. (a) Manhas, M. S.; Chawla, H. P. S.; Amin, S. G.; Bose, Ajay K. Synthesis 1977, 407-409; (b) Amin, S. G.; Glazer, R. D.; Manhas, M. S. Synthesis, 1979, 210-213. Manhas, M. S.; Amin, S. G.; Ram, Bhagat; Bose, Ajay K. Synthesis 1976, 689-690. (a) McGuire, M. A.; Hegedus, L. S. /. Am. Chem. Soc. 1982, 104, 5538-5540; (b) Hegedus, L. S.; Imwinkelried, R.; Alarid-Sargent, M.; Dvorak, D.; Satoh, Y. J. Am. Chem. Soc. 1990, 112, 1109-1117; (c) Hegedus, L. S. Tetrahedron 1997, 53, 4105—4128. See also reference 14. Garner, P.; Park, J. M. Org. Synth. 1991, 70, 18-28. (a) Jayaraman, M.; Deshmukh, A. R. A. S.; Bhawal, B. M. Tetrahedron 1996, 52, 89899004; (b) Jayaraman, M.; Puranik, V. G.; Bhawal, B. M. Tetrahedron 1996, 52, 9005-9016. (a) Palomo, C; Cossio, F. P.; Cuevas, C; Lecea, B.; Mielgo, A.; Roman, P.; Luque, A.; Martinez-Ripoll, M. J. Am. Chem. Soc. 1992,114, 9360-9369; (b) Shaikh, A. L.; Kale, A. S.; Shaikh, M. A.; Puranik, V. G.; Deshmukh, A. R. A. S. Tetrahedron 2007, 63, 3380-3388; (c) Shin, D. G.; Heo, H. J.; Jun, J.-G. Synth. Commun. 2005, 35, 845-855. Frazier, J. W.; Staszak, M. A.; Weigel, L. O. Tetrahedron Lett. 1992, 33, 857-860. (a) Araki, K.; OToole, J. C; Weilch, J. T. Bioorg. Med. Chem. Lett, 1993, 3, 2457-2460. (b) Welch, J. T.; Araki, K.; Kawcki, R.; Wichtowski, J. A. J. Org. Chem. 1993, 58, 24542462. Viso, A.; Fernandez de la Predilla, R.; Flores, R. Tetrahedron Lett. 2006, 47, 8911-8915. Del Buttero, P.; Molteni, G.; Papagni, A.; Miozzo, L. Tetrahedron: Asymmetry 2004, 15, 2555-2559. Jayaraman, M.; Deshmukh, A. R. A. S.; Bhawal, B. M. Tetrahedron 1996, 52, 3741-3756. (a) Van der Steen, F. H.; Van Koten, G. Tetrahedron 1991, 47, 7503-7524; (b) G. I. Georg, Z. Wu, Tetrahedron Lett. 1991, 35, 381-384; (c) Bourzat, J. D.; Commercon, A. Tetrahedron Lett, 1993, 34, 6049-6052; (d) Hashimoto, Y.; Kai, A.; Saigo, K. Tetrahedron Lett, 1995, 36, 8821-8224; (e) Srirajan, V.; Deshmukh, A. R. A. S.; Puranik, V. G.; Bhawal, B. M. Tetrahedron: Asymmetry 1996, 7, 2733-2738; (f) Abouabdellah, A.; Begue, J. P.; BonnetDelpon, D.; Nga, T. T. T. J. Org. Chem. 1997, 62, 8826-8833; (g) Gunda, T. E.; Sztaricskai, F. Tetrahedron 1997, 53, 7985-7998; (h) Brown, S.; Jordan, A. M.; Lawrence, N. J.; Pritchard, R. G.; McGown, A. T. Tetrahedron Lett. 1998, 39, 3559-3562. Jarrahpour, A. A.; Shekarriz, M.; Taslimi, A. Molecules 2004, 9, 939-948.

68 42. 43. 44. 45.

46. 47. 48.

49. 50. 51. 52. 53. 54. 55. 56. 57. 58. 59. 60. 61. 62. 63. 64. 65. 66. 67.

Name Reactions for Carbocyclic Ring Formations (a) Bose, A. K.; Manhas, M. S.; van der Veen, J. M.; Bari, S. S.; Wagle, D. R. Tetrahedron 1992, 48,4831^844; (b) Farina, V.; Hauck, S. I.; Walker, D. G. Synlett 1992, 761-763. Martin-Zamora, E.; Ferrete, A.; Llera, J. M.; Munoz, J. M.; Pappalardo, R. R.; Fernandez, R.; Lassaletta, J. M. Chem. Eur. J. 2004,10, 6111-6129. Fernandez, R.; Ferrete, A.; Lassaletta, J. M.; Llera, J. M.; Martin-Zamora, E. Angew. Chem., Int. Ed. Engl. 2002, 41, 831-833. (a) Evans, D. A.; Sjögren, E. B. Tetrahedron Lett. 1985, 27, 3783-3786; (b) Boger, D. L.; Myers, J. B. Jr. J. Org. Chem. 1991, 56, 5385-5390; (c) Müller, M.; Bur, D.; Tschamber, T.; Streith, J. Heb/. Chim. Acta 1991, 74, 767-773; (d) Duczek, W.; Jähnisch, K.; Kunath, A.; Reck, G.; Winter, G.; Schulz, B. Liebigs Ann. Chem. 1992, 781-787; (e) Alcaide, B.; MartinCantalejo, Y.; Perez-Castells, J.; Rodriguez-Lopez, J.; Sierra, M. A.; Monge, A.; PerezGarcia, V. J. Org. Chem. 1992, 57, 5921-5931; (f) Burwood, M.; Davies, D.; Diaz, I.; Grigg, R.; Molina, P.; Sridharan, V.; Hughes, M. Tetrahedron Lett. 1995, 36, 9053-9056; (g) Alcaide, B.; Martin-Cantalejo, Y.; Perez-Castells, J.; Sierra, M. A.; Monge, A. J. Org. Chem. 1996, 61, 9156-9163; (h) Palomo, C; Aizpurua, J. M.; Garcia, J. M.; Galarza, R.; Legido, M.; Urchegui, R.; Roman, P.; Luque, A.; Server-Carrio, J.; Linden, A. J. Org. Chem. 1997, 62, 2070-2079; (i) B. Alcaide, C. Polanco, M. A. Sierra, Eur. J. Org. Chem. 1998, 29132921; (j) Alcaide, B.; Rodriguez-Vicente, A. Tetrahedron Lett. 1999, 40, 2005-2006. Cremonesi, G.; Dalla Croce, P.; Fontana, F.; Forni, A.; La Rosa, C. Tetrahedron: Asymmetry 2005,7(5,3371-3379. Khasanov, A. B.; Ramirez-Weinhouse, M. M.; Webb, T. R.; Thiruvazhi, M. J. Org. Chem. 2004, 69, 5766-5769. (a) Borer, B. C; Balogh, D. W. Tetrahedron Lett. 1991, 32, 1039-1040; (b) Bhagwat, S. S.; Gude, C; Chan, K. Tetrahedron Lett. 1996, 37, 4627^*630; (e) Srirajan, V.; Deshmukh, A. R. A. S.; Bhawal, B. M. Tetrahedron, 1996, 52, 5585-5590; (d) Joshi, S. N.; Deshmukh, A. R. A. S.; Bhawal, B. M. Tetrahedron: Asymmetry 2000,11, 1477-1485. Trabocchi, A.; Lalli, C; Guarna, F.; Guarna, A. Eur. J. Org. Chem. 2007,4594-4599. Chincholkar, P. M.; Puranik, V. G.; Deshmukh, A. R. A. S. Synlett 2007,2242-2246. Niu, C; Petterson, T.; Miller, M. J. J. Org. Chem. 1996, 61, 1014-1022. Ojima, I.; Chen, H.-J. C; Qiu, X. Tetrahedron 1988, 44, 5307-5318. Palomo, C; Aizpurua, J. M.; Mielgo, A.; Linden, A. J. Org. Chem. 1996, 61, 9186-9195. Bandini, E.; Martelli, G.; Spunta, G.; Panunzio, M. Synlett 1996, 1017-1018. See also reference 53. Taggi, A. E.; Hafez, A. M.; Wack, H.; Young, B.; Drury, W. J., Ili; Lectka, T. J. Am. Chem. Soc. 2000,122, 7831-7832. Hodous, B. L.; Fu, G. C. J. Am. Chem. Soc. 2002, 124, 1578-1579. The catalyst is commercially available from Strem. Lee, E. C; Hodous, B. L.; Bergin, E.; Shih, C; Fu, G. C. J. Am. Chem. Soc. 2005, 127, 11586-11587. [R] (a) Taggi, A. E.; Hafez, A. M.; Lectka, T. Ace. Chem. Res. 2003, 36, 10-19; [R] (b) Fu, G. C. Ace. Chem. Res. 2004, 37, 542-547; [R] (c) France, S.; Weatherwax, A.; Taggi, A. E.; Lectka, T. Ace. Chem. Res. 2004, 37, 592-600. Taggi, A. E.; Hafez, A. M.; Wack, H.; Young, B.; Ferraris, D.; Lectka, T. J. Am. Chem. Soc. 2002,124, 6626-6635. Shah, M. H.; France, S.; Lectka, T. Synlett 2003, 1937-1939. Wack, H.; France, S.; Hafez, A. M., Drury, W. J. Ill; Weatherwax, A.; Lectka, T. J. Org. Chem. 2004, 69, 4531^1533. France, S.; Shah, M. H.; Weatherwax, A.; Wack, H.; Roth, J. P.; Lectka, T. J. Am. Chem. Soc. 2005,727, 1206-1215. Weatherwax, A.; Abraham, C. J.; Lectka, T. Org. Lett. 2005, 7, 3461-3463. Sereda, O.; Wilhelm, R. Synlett 2007, 3032-3036. Zhang, Y.-R.; He, L.; Wu, X.; Shao, P.-L.; Ye, S. Org. Lett. 2008,10, 277-280. Duguet, N.; Campbell, C. D.; Slawin, A. M. Z.; Smith, A. D. Org. Biomol. Chem. 2008, 6, 1108-1113. [R] Bose, A. K.; Manhas, M. S.; Mathur, A.; Wagle, D. R. In Recent Progress in the Chemical Synthesis of Antibiotics and Related Microbial Products, Vol. 2; Lukacs, G., Ed.; Springer-Verlag, Heidelberg, 1993, pp 551.

Chapter 2 Four-Membered Carbocycles 68. 69. 70. 71. 72. 73.

74. 75. 76.

69

Pathak, V. N.; Gupta, R.; Garg, M. Heteroat. Chem. 2004,15, 494-501. Fernandez, R.; Ferrete, A.; Lassaletta, J. M.; Llera, J. M.; Monge, A. Angew. Chem., Int. Ed. Engl. 2000, 39, 2893-2897. (a) Jarrahpour, A.; Zarei, M. Molecules 2007, 12, 2364-2379; (b) Jarrahpour, A.; Zarei, M. Synth. Commun. 2008, 38, 1837-1845. Cremonesi, G.; Dalla Croce, P.; Fontana, F.; La Rosa, C. Tetrahedron: Asymmetry 2008, 19, 554-561. Berlin, J. M.; Fu, G. C. Angew. Chem., Int. Ed. Engl. 2008, 47, 7048-7050. (a) Ojima, I.; Habus, I.; Zhao, M.; Zucco, M.; Park, Y. H.; Sun, C. M; Brigaud, T. Tetrahedron, 1992, 48, 6985-7012; (b) Holton, R. A.; Liu, J. H. Bioorg. Med. Chem. Lett. 1993, 3, 2475-2478; (c) Nicolaou, K. C; Dai, W.-M.; Guy, R. K. Angew. Chem. Int. Ed. Engl. 1994, 33, 15-44; (d) Srirajan, V.; Deshmukh, A. R. A. S.; Bhawal, B. M. Tetrahedron 1996, 52, 5585-5590; (e) Kingston, D. G. 1. Chem. Commun., 2001, 867-880. Alajarin, M.; Vidal, A.; Tovar, F. Tetrahedron 2005, 61, 1531-1537; Oshitari, T.; Mandai, T. Synletl 2009, 787-789. Vincent, G.; Williams, R. M. Angew. Chem., Int. Ed. Engl. 2007, 46, 1517-1520.

Name Reactions for CarbocycUc Ring Formations Edited by Jie Jack Li Copynght © 2010 John Wiley & Sons, Inc.

Chapter 3. Five-Membered Carbocycles

71

3.1 3.2 3.3 3.4 3.5 3.6

72 93 109 122 147 181

Danheiser Annulation Dieckmann Condensation Favorskii Rearrangement Nazarov Cyclization Pauson-Khand Reaction Weiss-Cook Reaction

72

3.1

Name Reactions for Carbocyclic Ring Formations

Danheiser Annulation

Kevin M. Peese 3.1.1 Description 0

Me3Sk

VÌI * Ì

r

R2

1

R2 3Xj^SiMe3

- ft

R 3 SK ^ R 2 electrophile +

0

Lewis acid

"~

1

4

(

^SiR3 5

The Danheiser annulation, in its classic form, is the Lewis acid-catalyzed reaction of an a,/?-unsaturated ketone 1 with a trimethylsilylallene 2 to form a silyl cyclopentene 3.1"3 More broadly, the Danheiser annulation ecompasses reactions of silylallenes 4 with electrophilic double bonds to form cyclic products 5, usually under Lewis acid catalysis. The Danheiser annulation should not be confused with other annulation processes developed by Danheiser, such as Danheiser's aromatic annulation and the Stork-Danheiser alkylation.5 R3Sk 4

R

II

=

".:>

—SiR3

The defining feature of the Danheiser annulation is the use of a silylallene 4 as a three-carbon synthon 6 in a step-wise cycloaddition reaction. The annulation process is always initiated by the attack of the nonsilyl substituted position of the silyl aliene onto the electrophilic double bond to generate a silyl-stablized vinyl cation at the central carbon atom. After a 1,2-sp2-silyl migration, which places the silyl group onto the central carbon of the former aliene, ring closure occurs, yielding a 5-membered ring. The electrophile can be activated by complexation to a Lewis acid; however, silylallenes will react with most strongly electrophilic double bonds. A diverse array of electrophiles have been shown to participate in the annulation process, leading to a variety of annulation products beyond

Chapter 3 Five-Membered Carbocycles

73

cyclopentenes, such as furans, dihydrofurans, dihydro-pyrroles, isoxazoles, and azulenes. 3.1.2

Historical Perspective

The discovery of the Danheiser annulation was serendipitous as it came out of research directed at a different synthetic challenge.6 In the late 1970s, there were no satisfactory methods available for the addition of propargylic anions, where the anion is centered at the sp3 carbon, to carbonyl compounds. Whereas addition of allylic organometallics 8 such allylmagnesium halides or allyllithiums to carbonyl compounds 7 efficiently produces homoallylic products 9, the analogous reaction of propargylic organometallic reagents 10 with carbonyl compounds 7 produces mixtures of homopropargylic alcohols 11 and allenic alcohols 12. In this context, Danheiser proposed that the use of a silylallene instead of an alkyne-based reagent could deliver the homopropargylic alcohol products selectively. O R1

OH R2

R2

M = MgX, Li

9

M

- ^ R 10

O

Ri

R2

M = MgX, Li

3

Ri R2

OH

3

OH

Q

2

11

12

mixture

Investigation of the TiCU-catalyzed electrophilic addition of aldehydes and ketones 7 onto silylallenes 13 produced moderate to high yields of the desired homopropargylic alcohol product 14.7 It was surprising that in some cases the reaction produced a mixture of the expected homopropargylic alcohol 14 along with the trimethylsilylvinyl chloride product 16. This result suggested that the intermediate silylvinyl cation 15 was relatively stable and the desilylation step was not as rapid a process as might have been expected. Preparatively, production of silylchloroalkenes 16 did not prove to be an issue as the crude reaction mixtures could be treated with KF in DMSO to efficiently convert the trimethylsilylvinyl chlorides 16 to the desilylated product alkynes 14.

74

Name Reactions for Carbocyclic Ring Formations

F

0

^•^SiMe 13 TiCI 4

7

CH2CI2 r* - 7 8 °C to 23 °

OTiCU

0 Ri

R2

^SiMe 3 2

».

3

2

_

y^* R2

15

OH

14

R OH CI * R'AA

^.

_

R2

14

mixture

16

SiMe?

Seeking to expand the scope of the transformation, Danheiser investigated the use of an a,/?-unsaturated ketone as the electrophilic component in the homopropargylic alcohol synthesis.6 The first reaction attempted was that of cyclohexenone (17) with silylallene 18 using TiCU as a Lewis acid catalyst. After treatment of the initial isolated product 19 with fluoride, a,/?-unsaturated ketone 20 was isolated as the major product. After verification of the structure of a,/?-unsaturated ketone 20, the course of the reaction could be deduced. ;-Pr /-Pr

TiCI 4 ^·

SiMe 3

F

3

CH2CI2 - 7 8 °C to 23 °C

In the expected course of the reaction, the electrophile combines with the silylallene resulting in the intermediate silylvinyl cation 21, which either undergoes desilylation to produce the expected product alkyne 22 or traps chloride ion to produce vinylchloride 23. In the case of the annulation reaction, the intermediate silylvinyl cation 21 underoes an apparent 1,2-sp silyl migration process. The resulting isomerie silylvinyl cation 24 is then able to react with the pendent titanium enolate leading to the observed annulation product 25.

Chapter 3 Five-Membered Carbocycles

75

ClaTi desilylation CUTiR

S i M e 3 ° c i trapping

3

K

OMe3Si

1,2-sp2-silyl\^C|3Ti migration SiMe-,

It was fortuitous that isopropy silylallene 18 was the first aliene investigated as it was later found that substitution ipso to the silyl group is necessary to obtain preparatively useful yields (> 20%).6 Indeed, in the previous year during investigations of the very similar TiCU-catalyzed reaction of oc,/?-unsaturated ketones and a,/?-unsaturated esters with 1unsubstituted silylallenes, Santelli and Jellal did not report observing the formation of cyclopentenyl annulation products.8 Further investigation of the annulation process by Danheiser demonstrated it to be quite general and synthetically useful. Results of these initial studies detailing the discovery and scope of the annulation process were then published in 1981.1 Since the initial publication, a number of interesting synthetically useful variations have been disclosed, greatly expanding the variety of electrophiles that can be used in the annulation reaction (vide infra). 3.1.3

Mechanism

General Mechanism The generally accepted mechanism of the classic Danheiser annulation involves three basic steps: the Lewis acid-catalyzed electrophilic combination of the a,/?-unsaturated ketone with the silylallene, a 1,2-sp -silyl migration, and a final cyclization step. This mechanism was first proposed by Danheiser in the original publication of the annulation and has been generally accepted but has never been formally investigated.1 A more detailed account of the reaction pathway is shown below. Treatment of the oc,/?-unsaturated ketone 1 with TiCU produces a titanium complex existing as two resonance-stablized cations 26 and 27. Attack of the 2,3-7i-bond of the

Name Reactions for Carbocyclic Ring Formations

76

silylallene 2 onto the strongly electrophilic titanium complex 27 produces the silyl-stablized vinyl cation 21. Silylvinyl cation 21 exists in equilibrium with the isomerie silylvinyl cation 24 via a 1,2-sp2-silyl migration. Finally, intramolecular attack of the titanium enolate moiety produces cyclopentene 3. It is important to note that silylvinyl cation isomer 21 does not undergo annulation, since formation of the cyclobutane product is predicted to be highly disfavored and consequently is not observed. CUJU

CUTi 3"^,TiCL

R'

1©

^

26

-neu

R R

R. / S i M e 3

27

CI 3 Tk

W

®/R.

^—SiMe

1,2-shift

T,

:, 2

©

CkTU R^ ^SiMe 3

SiMe, 21

24

For the reaction to proceed in reasonable yields, substitution on the terminal position of 2 (R Φ Η,) is required. This is likely due to the predicted relative higher energy of the terminal vinyl cation 28 compared to the internal vinyl cation 29. Thus without substitution, equilibrium of the two vinyl cations 28 and 29 strongly favors the internal cation isomer 29 which does not undergo cyclization but rather undergoes desilylation to afford the terminal alkyne product 30.7 CUTU

CI3TkQ H

R

1,2-shift

\© SiMe·,

28

R

I

CI3Tk0 H^.SiMes

~ i3 29

-SiMe 3

—""

When other electrophiles besides cc,/?-unsaturated ketones are used, the mechanism is analogous, however, care must be taken to ensure that direct desilylation of acyclic intermediate 31, to form acyclic alkyne 32 does not occur. It is interesting that the use of more sterically encumbered alkylsilanes, for example fóri-butyldimethylsilyl rather than trimethylsilyl, increases the selectivity of the reaction for the cyclized product versus the acyclic alkyne 32 that is produced by desilylation of silylvinyl cation 31.

Chapter 3 Five-Membered Carbocycles

77

Danheiser has postulated that this is due to the need for chloride to initiate desilylation; sterically large silyl groups should disfavor the approach of chloride to the silyl group. Thus some variations of the Danheiser annultion are practical only with silanes that are sterically larger than trimethylsilyl in order to avoid desilylation of the vinyl cation intermediate (vide infra).

annulation

slow for -SiR3 other than -SiMe3

B

A V ^SiR3

31 V.

Cl

CISÌR3

Stereochemical Considerations Stereochemical investigation of the Danheiser annulation demonstrated that the cyclization usually proceeds with a high degree of stereoselectivity. Annulation of (£)-enone 33 affords a single diastereomer, cyclopentene 35, in which the methyl group and the acetyl group are oriented anti to one another, the result of an apparent suprafacial attack of the aliene on the α,βunsaturated ketone. Likewise, annulation of trisubstituted a,/?-unsaturated ketone 36 provides a single diastereomer, cyclopentene 37, once again the result of an apparent suprafacial attack of the aliene on the a,/?-unsaturated ketone. For isomerie a,/?-unsaturated ketone 38, annulation also proceeds with high stereoselectivity, but in this case the other diastereomer 37, can be detected in trace amounts. Taken together, these results suggest that the rate of ring closure is significantly faster than the rate of enolate rotation, giving rise to the appearance of suprafacial attack of the aliene onto the α,βunsaturated ketone. For allenes substituted at the 3-position, the annulation reaction proceeds with moderate to good stereoselectivity. For example, treatment of cyclopentenone (40) with aliene 41 under standard conditions gives predominantly cyclopentene 42 with the methyl group in an exo orientation. Me

34 Ί

^.^SiMe3 TiCI4

Me CH 2 CI 2 ,-78°C

Me Me' Me

^ 35

^—SiMe-, 79%

Name Reactions for Carbocyclic Ring Formations

78

Me Me


Me CH 2 CI 2 ,-78°C

37

71%

Me ^•^SiMe3 TiCU

-

?MeMe M e /

CH2CI2, -78 °C

T V s i M e

>--/ Me 39

Me

O

.A,

M e ^ ^ · - ^ . SiMe3

O

H

^— c|^

CH2CI2, -78 °C 40

0

Me

SiMe3

3 +

(13-19:1) 68% Q _

Me

siMe3

H Me 42

-■

+

(3:1) 68%

nH

<4^ H

43

Me.

siMea

Me

3.1.4 Synthetic Utility Silyl Aliene Scope The key component of the Danheiser annulation is the silylallene on which there are three points of diversity: the carbon bearing the silyl group; the silyl group itself; and the distal 3-position carbon. Of critical importance is the need for carbon substitution ipso to the silyl group in the silyl aliene 44 (R Φ H) to obtain preparatively useful yields (> 20%) of the cyclized product. Without substitution, the 1,2-sp2-silyl migration becomes disfavoured, leading to predominantly nonannulated products, the acyclic alkyne and the silylvinyl chloride. For example, during early investigations of the annulation process, Danheiser found that reaction of cyclohexenone 17 with the unsubstituted parent aliene, trimethylsilylallene 13, under standard conditions led consistently to only low yields of the annulated cyclopentene product 45 (17-19%).2 With respect to the substitution on the silyl group, a variety of silyl moieties have been shown to participate in the annulation process including -SiMe3 (-TMS), -SiMe2i-Bu (-TBS), and -Si/-Pr3 (-TIPS).

79

Chapter 3 Five-Membered Carbocycles

For the distal position of the aliene, C-3 with respect to the silyl group, both hydrogen and alkyl substitution is tolerated. Only at the extreme limit of steric congestion of both the aliene and the enone are low yields observed. For example, reaction of /?-dimethyl ot,/?-unsaturated ketone 46 with 3,3dimethylallene 47 under standard conditions provides only 7% yield of the cyclopentene product 48.2 RaSU

-Ri

R-i = alkyl SiR 3 = SiMe 3 , SiMe 2 f-Bu, Si/-Pr3 R2, R3 = alkyl or H

44 R3

R2

^•^SiMe TiCI 4

3

+~

CH2CI2 - 7 8 °C to 23 °C

SiMe 3

Me

Me

TiCI

4

Me CH 2 CI 2 , - 7 8 °C

SiMe 3

Cyclopentene Synthesis The original application of the Danheiser cyclization was for the preparation of cyclopentenes employing a,/?-unsaturated ketones as the electophilic component of the annulation process. A variety of a, /?-unsaturated ketones with various alkyl substitution patterns readily participate in the Danheiser annulation. ' In addition to a,/?-unsaturated ketones, ct,/?-unsaturated esters also undergo cyclization, albeit at much slower rates than the corresponding α,βunsaturated ketones.2 Treatment of methyl acrylate (49) with silylallene 34 at 25 °C (rather than the standard -78 °C) in the presence of TiCU furnished the expected cyclopentene 50 in 49% yield. To access carboxylate derivatives, Danheiser has reported the use of oc,/?-unsaturated acylsilanes as the electrophilic component in the annulation process producing the corresponding acylsilane substituted cyclopentenes.10 The acylsilane can then

Name Reactions for Carbocyclic Ring Formations

80

be readily oxidized to afford the carboxylic acid. For example, treatment of cc,/?-unsaturated acylsilane 51 with silylallene 34 under standard conditions affords cyclopentene 52, which then undergoes oxidation with F^C^/NaOH in aqueous THF at 40 °C to give carboxylic acid 53. Care must be exercized in maintaining the reaction at -78 °C when using an a,/?-unsaturated acyltrimethylsilanes as the electrophilic component since at warmer temperatures the acyltrimethylsilanes cyclopentene annulation product undergoes ring expansion under the reaction conditions, providing a sixmembered ring product. Me <ί? 34~ SiMe 3 TiCI 4

MeO'

Me ft

MeO

^SiMe

CH 2 CI 2 , 25 °C

49

50

3

49%

Me 4? f-BuMe 2 Si'

51

3^SiMe3 TiCI 4

Me f-BuMe2Si

^SiMe,

CH 2 CI 2 , - 7 8 °C

52 72% H 2 0 2 , NaOH THF, water

40 °C

O

Me

HO

\

SiMe·,

53 81% Me ^.^SiMe 34 Me3Si

3

\f

TiCU CH 2 CI 2 ,-50°C

55

56%

SiMe·,

Chapter 3 Five-Membered Carbocycles

81

via (proposed): CI 3 Tk © || M e M e Me3sr^^\

TiCI3

Me3S\Sp M e X > C .Me SiMe57

56

59 (2 equiv) gg"SiMe2f-Bu poly(4-vinylpyridine) *MeCN, 23 °C Me

Me

Me

r

SiMe,

ft

T / V " SiMe2f-Bu 60

Me

SiMe2f-Bu 61

Me 52-59%

Me 59 J^ (3 equiv) ^· SiMe2f-Bu poly(4-vinylpyridine) 62 1:1 heptane: MeCN 65 °C

SiMe2f-Bu

The Danheiser annulation has also been reported to be useful for the preparation of substituted azulene products.11 For example, treatment of silylallene 58 with tropylium cation 59 at 23 °C produces intermediate cyclopentene dihydroazulene 60, which is not isolated but rather undergoes in situ dehydrogenation with a second equivalent of tropylium cation 59 to provide azulene 61. The use of thefóri-butyldimethylsilylgroup as opposed to the trimethylsilyl group is necessary since the trimethylsilyl group tends to undergo premature desilylation rather than cyclization to the azulene. Substitution at the 3-position of the aliene was also found to significantly

82

Name Reactions for Carbocyclic Ring Formations

improve the yield of the reaction. For example, the reaction of silylallene 62 (unsubstituted at the 3-position) with tropylium cation 59 afforded the product azulene 63 in only 22% yield compared to the 52-52% yield obtained with the 3-substituted silylallene 61. The use of other electrophiles in the Danheiser annulation for the formation of cyclopentenes is relatively unexplored. Ynones have been reported to undergo cycloaddition, although examples are limited.2 Thus treatment of butynone 64 with silyl aliene 47 under the usual conditions delivered cyclopentadiene 65 in 53% yield. Danheiser has reported that nitroalkenes do not provide annulation products furnishing instead acyclic alkynes.2 For example, treatment of nitroalkene 66 with silylallene 34 under standard conditions gives alkyne 67 rather than the cyclopentene 68. α,βUnsaturated aldehydes have been reported to be problematic, failing to provide isolable cyclopentene products.2 Treatment of methacrolein (69) with silylallene 34 under the standard conditions produced only a complex mixture of unidentified products. Me

4? SiMe 3

Me

">f

Me TiCU

Me 64

53%

Me OoN

SiMe-,

CH2CI2, -78 °C

^•^SiMe3

0,N

TiCI4

SiMe?

». CH2CI2, -78 °C Ph^

67 58%

observed

Me ^•^SiMe TiCI4

[l Me

3

*CH2CI2, -78 °C

complex mixture

Me

SiMe·, 70 not observed

83

Chapter 3 Five-Membered Carbocycles

Furan and Dihydrofuran Synthesis Dihydrofuranso '' and furans,13 are accessible through the Danheiser annulation using aldehydes and acid chlorides, respectively, as electrophilic component in the Danheiser annulation. The pivitol advance to allow practical access to dihydrofurans and furans, however, was the recognition that the use of more sterically encumbered alkylsilanes, i.e., tertbutyldimethylsilyl rather than trimethylsilyl, is critical to obtaining the annulation product selectively over the undesired noncyclized alkyne product. For instance, treatment of aldehyde 71 with trimethylsilylallene 34 under standard conditions, results in an 85% yield of acyclic alkyne 72 7a formally the product of propargyl addition to the aldehyde, whereas using the teri-butyldimethylsilylallene 62 affords the dihydrofuran 73 in 70% yield.9 9 12

Me 34^SiMe3

^

TiCI4 »■

CH2CI2, -78 °C

Me ^•^SiMe2f-Bu TiCI4

». CH2CI2, -78 °C

SiMe2f-Bu

Me Me^ji-· gg~SiMe2i-Bu 9

TiC!4

Me" H 74

CH2CI2, -78 °C

ΜΘ O Me'

V Me 75

Me

SiMe2i-Bu 1.4:1 78%

Me'

SiMe2f-Bu Me 76

The reaction of silylallenes with aldehydes to form dihydrofurans is applicable to a variety of alkyl aldehydes, including substrates such as acetaldehyde (74), cyclohexylaldehyde (77), and pivaldehyde (80).9 When

Name Reactions for Carbocyclic Ring Formations

84

the silyllallene is substituted at the 3-position, the reaction diastereoselectively provides the syn products, with increasing selectivity as the steric bulk of aldehyde increases. Me M e ^ ^ · go"SiMe2i-Bu

Me

TiCU H

V

CH2CI2, -78 °C

SiMe2f-Bu

SiMe2f-Bu

Me 78

77 Me O

/-BLI

M e ^ ^ · g^SiMe2f-Bu

X

80

Me

TiCU H

CH2CI2, -78 °C

SiMe2f-Bu

f Bu

" '

SiMe2f-Bu

f-Bu

92%

Me 82

not observed

Furans can be prepared using acid chlorides as the electrophilic component in the Danheiser annulation, which allows for the preparation of highly substituted derivatives.13 Both alkyl and aryl acid chlorides undergo the furan synthesis. For silylallenes lacking substitution at the 3-position, it is necessary to use triisopropylsilyl as the silyl group on the aliene. This is due to the propensity of the unsubstituted furan products to undergo further Friedel-Crafts type acylation reactions at the unsubstituted CH position of the furan under the reaction conditions. A sufficiently bulky silyl group prevents this from happening since the sterically demanding silyl group effectively shields this site from further reactivity.

cor 83

Me

Et " A SiMe2f-Bu AICU

CH2CI2, -20 °C

, ^

, II 85

Et.

SiMe2f-Bu

// w

71%

Chapter 3 Five-Membered Carbocycles

85

Me

rrr \ ^

^.^Si/-Pr3 86 AICk

CI °

83

CH2CI2 -20 °C

Dihydropyrrole Synthesis Dihydropyrroles can be prepared through the Danheiser annulation by utilizing iV-acylimminium ions as the electrophile. ' Similar to the method used to prepare dihydrofurans and furans, sterically encumbered silyl groups are necessary to obtain useful yields of the dihydropyrrole annulation products.9 For example, treatment of aminal 88 with trimethylsilylallene 34 and TiCU provides a mixture of pyrrolizinone 89 (28%) and acyclic alkyne 90 (59%). The analogous reaction using the ter/-butyldimethylsilylallene analogue 62 affords the annulation product of pyrrolizinone 91 exclusively in 63% yield. A single example involving an acyclic TV-acylimminium electrophile gave a lower yield suggesting that cyclic 7V-acylimminium substrates are preferred for the annulation reaction. Me O

^»^SiMe3

<^ H

TiCI

O

Me

/ S ^ - c i SiMe u - .3 * ΛΥΗ

4

OEt CHz2CIz2) 0 to 25 °C 88

89 28%

90 59%

Me O

^.^SiMezf-Bu O

/"NH

<J|

TiCI4

-

-

OEt CHί2CIζ2, 0 to 25 °C 88

Me

Λ Ν Λ

(

7* ^SiMe2i-Bu

91 63%

„Me

Name Reactions for Carbocyclic Ring Formations

86

Me ^.•■^2SMe2t-Bu TiCI4

NH

Me'

0

Me

Of-Bu CH 2 CI 2 , 0 to 25 °C

92

Me

Isoxazole Synthesis

SiMe 2 i-Bu 93 25%

Isoxazoles are accessible through the Danheiser annulation using nitrosonium as the electrophilic component.15 For the annulation reaction of trimethylsilyl allenes, the corresponding isoxazole annulation product tends to undergo partial protodesilylation during the reaction. The desilylation process can be driven to completion after isoxazole formation is complete by adding water to the reaction and heating until protodesilylation is complete. For fóri-butyldimethylsilylallenes, no desilylation occurs and the silyl isoxazoles can be isolated directly.

NOBF4 SiMe, 93

MeCN

water SiMe·,

· -30 °c

Me ^•^SiMe2f-Bu 62

MeCN, 70 °C

& \ N

NOBF4 MeCN, - 3 0 °C

SiMe2f-Bu 96 87%

Formal [3 + 3] Processes Two methods for accomplishing a formal [3 + 3] cycloadditions using the Danheiser annulation have been reported.16'17 Angle et al. reported that formation of dihydronaphthalene 99 was formed in 77% yield from the reaction of benzyl alcohol 97 with silylallene 98 in the presence of SnCU 16 Alternatively, the use of hydroxysubstituted benzyl alcohols provides the spirofused cyclopentene products. Treatment of hydroxybenzyl alcohol 100 with silylallene 98 in the presence of SnCU produces spirocyclopentene 101 in 76% yield. Depending on the nature of the substituents on the aryl ring, mixtures of dihydronaphthalenes and spirocyclopentenes may be obtained.

Chapter 3 Five-Membered Carbocycles

87

Unfortunately, the method requires an excess of either the benzyl alcohol or the silylallene to obtain moderate yields. Me Me^^.»^SiMe 2 i-Bu

Vee

Me SnCI4 CH2CI2, 0 °C

SiMe2f-Bu 1

Me v ^ · 9^SiMe2f-Bu : SnCI4

°SiMe2f-Bu

CH2CI2, 0 °C

Yadav et al. have reported using cyclopropanes as the electrophilic component in the Danheiser annulation leading to the formation of cyclohexene products.17 Treatment of cyclopropane 102 with Et2ÄlCl at 25 °C resulted in ring opening of the cyclopropane, which then underwent reaction with silylyallene 34 to afford cyclohexene 103, formally a [3 + 3] annulation product. Me

SiMe2f-Bu

Ph O

102

/ • ^ SiMe-, * 34 Et2AICI CH2CI2, 25 °C

SiMe, SiMe2f-Bu

Enantioselectivity Two reports of enantioselective Danheiser annulations have appeared in the literature.12'14 Evans et al. have reported the annulation of ethyl glyoxylate (104) to form dihydrofuran products in good to excellent enantioselectivity using a chiral scandium catalyst.12 For example, reaction of ethyl glyoxylate (104) with teri-butyldiphenylsilylallene 105 in the presence of the chiral scandium catalyst 106 led to dihydrofuran 107 in 91% yield and 92% ee. As

Name Reactions for Carbocyclic Ring Formations

88

with Danheiser's previous studies regarding the formation of dihydrofurans, sterically encumbered silanes were found to be necessary to obtain the annulation product as opposed to the acyclic alkyne byproduct.

-N—Sc—NTfO' I 'OTf "i Ph OTf Ph 0 II

M e J

6 10mo |% I U ΓΠΟΓ/0

8

Α,ϋ * X ^ " * * CHA^-C O

104

2

105

E,

2

Me 0 <-»

\Λ

°Y''^>SiPh2'-Bu o 107 91%(92%ee)

Akiyama et al. have reported the annulation of iminoesters to form dihydropyrrole products with moderate enantioselectivities using a chiral copper catalyst.14 Reaction of iminoester 108 with triisopropylsilylallene 86 with a chiral copper catalyst afforded dihydropyrrole 110 in 92% yield and 84% ee.

Ts \ E t 0

i^H + O 108

Ar= 3,5-Me2-Ph [Cu(MeCN)4]BF4 10mol%

„ Ψ ^Si/-Pr 86

3

benzene, reflua

B

° O 110

92% (84% ee)

Synthetic Utility of Silylalkene Annulation Products The silylalkene containing annulation products produced in the Danheiser annulation are themselves useful interemediates in organic synthesis. Danheiser demonstrated the protodesilylation of the silylcyclopentene annulation products in early studies.2 Treatment of silylalkene 111 with K2CO3 in methanol effected isomerisation and protodesilylation to produce isomerized cc,/?-unsaturated ketone 112 in 68% yield. Silyl-substituted

Chapter 3 Five-Membered Carbocycles

89

aromatic heterocycles readily undergo protodesilylation.11'15 Silylsubstituted furan 85 underwent smooth desilylation on exposure to HF.pyridine in THF to provide desilylated furan 113 in 86% yield.11 Me Me'

\

to Me

K2C03 -SiMe·,

111 ,SiMe2f-Bu

Me

MeOH

68%

HF-pyridine THF, 25 °C 113 86%

Friedel-Crafts acylation of silylalkene annulation products has been demonstrated. For example, treatment of silylalkene 111 with acetylchloride in the presence of AICI3 generated ct,/?-unsaturated ketone 114 in 95% yield.2 More sensitive substrates are also amenable to Friedel-Crafts acylation. Treatment of silylalkene 107, a chiral dihydrofuran, to similar conditions produced the acyl product 115 in 84% yield.12 Bromination of silyl substituted isoxazoles has also been demonstrated.15 Me Me'

SiMe·, !» 111 O

A o

EtO

L>Me

107 SiPh2f-Bu

Me

U

AcCI, AICI3 CH2CI2, 0 °C

114L---/

\ Me

95% AcCI, AICI3 CH2CI2, 0 °C

0 j

EtO

[>Me 115 γ^

84%

Me

> 0

3.1.5 Application in the Total Synthesis of Natural Products The Danheiser annulation has been featured in the formal total synthesis of the natural products (±)-clavukerin (116) and (±)-isoclavukerin (117) reported by Schäfer and coworkers.18 Cycloheptenone 118 was prepared in a three-step sequence from cycloheptadiene. Cycloheptenone 118 was then

Name Reactions for Carbocyclic Ring Formations

90

treated with trimethylsilylallene 34 in the presence of T1CI4 to afford a readily separable mixture of racemic cyclopentenes 119 and 120 in a 1:1 ratio and 91% combined yield. After base-catalyzed isomerization and fluoridemediated protodesilylation, a,/?-unsaturated ketone 121 was produced, α,βUnsaturated ketone 121 served as an intermediate in earlier syntheses of (±)clavukerin (116), thus providing a formal total synthesis of 116.19 In a similar manner, isomerie cyclopentene 120 was converted to the analogous a,/?-unsaturated ketone, which was also an intermediate in an earlier synthesis of (±)-isoclavukerin (117).19a Me

H 116 Me clavukerin

H 117 Me isoclavukerin

Me ^•^SiMe

3

TiCI4 + Me3Si

-*- Me3Si CH 2 CI 2 , - 7 8 °C 118

(1:1) 91% 1)K,CCK \ 2 v ^ 3 , MeOH 23 °C

Me3Si

Me

>

ref. 19

116 clavukerin

►

2) TBAF, MeOH Me 121 78%

2.1.6 Experimental O Me ·=( Me 1 2 2 R-(-)-carvone

34

SiMe,

° M e Me TiCL CH2CI2 -75 °C to 0 °C

SiMe-j

82%

Chapter 3 Five-Membered Carbocycles

91

ci's-4-ex;o-Isopropenyl-l,9-dimethyl-8-(trimethylsilyl)bicyclo[4.3.0]non-8en-2-one (123)3 A 500-mL, three-necked, round-bottomed flask is equipped with a 25-mL pressure-equalizing dropping funnel, a mechanical stirrer, and a Claisen adapter fitted with a nitrogen inlet adapter and a low-temperature thermometer. The flask is charged with (i?)-(-)-carvone 122 (115 g, 0.077 mol), 1-methyl-l-(trimethylsilyl)allene 34 (10.8 g, 0.079 mol), and dry dichloromethane (180 mL), and then cooled below -75 °C with a dry iceacetone bath while a solution of titanium tetrachloride (17.4 g, 0.092 mol) in dichloromethane (10 mL) is added dropwise over 1 h. After 30 min, the cold bath is removed, and the reaction mixture, which appears as a red suspension, is allowed to warm to 0 °C over approximately 30 min. The resulting dark red solution is poured slowly into a 2-L Erlenmeyer flask containing a magnetically stirred mixture of diethyl ether (400 mL) and water (400 mL). The aqueous phase is separated and extracted with ether (2 χ 200 mL). The combined organic phases are washed with water (250 mL) and saturated sodium chloride solution (250 mL), dried over anhydrous magnesium sulfate, and concentrated at reduced pressure using a rotary evaporator. The residual yellow liquid is distilled through a 15-cm Vigreux column at reduced pressure to afford bicyclonoenone 123 (17.5 g, 82%) as a very pale yellow liquid. _

CI

Et

.

O

\^> 83

84

"<>

AICI3

SiMe2f-Bu

CH2CI2 ~20 ° c

Et

f**\ x

^ ^

SiMe^-Bu ^

71%

2-Benzyl-4-(teri-butyldimethylsilyl)-3-ethyl-5-methylfuran (85)

13

A 50-mL, one-necked, round-bottomed flask equipped with a three-way argon inlet adapter fitted with a rubber septum was charged with AICI3, (0.836 g, 6.27 mmol) and of CH 2 C1 2 (12 mL) and then cooled to -20 °C while phenylacetyl chloride (0.97 g, 6.27 mmol) was added rapidly via a syringe over ca. 1 min. After 5 min, a solution of aliene 84 (1.294 g, 6.26 mmol) in CH2CI2 (13 mL) was added dropwise via a syringe over the course of 1 min. The resulting orange reaction mixture was stirred at -20 °C for 1 h and then quenched by the addition of triethylamine (0.950 g, 9.39 mmol) in pentane (25 mL). The resulting solution was stirred at room temperature for 10 min, diluted with an additional 25 mL of pentane, and then washed with 10% HC1 solution (2 χ 50 mL), 3% NaOH solution (50 mL), water (50 mL),

92

Name Reactions for Carbocyclic Ring Formations

and saturated NaCl solution (50 mL). The organic phase was dried over K2CO3, filtered, and concentrated to afford a light yellow oil (ca. 1.5 g). Column chromatography on silica gel (elution with 1% triethylamine in petroleum ether) provided (1.39 g, 71%) of silylfuran 85 as a colorless oil. 3.1.7 References 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18. 19.

Danheiser, R. L.; Carini, D. J.; Basak, A. J. Am. Chem. Soc. 1981, 103, 1604-1606. Danheiser, R. L.; Carini, D. J.; Fink, D. M.; Basak, A. Tetrahedron 1983, 39, 935-947. Danheiser, R. L.; Fink, D. M.; Tsai, Y.-M. Org. Synth. 1988, 66, 8-13. Danheiser, R. L.; Gee, S. K. J. Org. Chem. 1984, 49, 1672-1674. (b) Smith, A. B. Ill; Adams, C. M; Kozmin, S. A.; Paone, D. V. J. Am. Chem. Soc. 2001,123, 5925-5937. (a) Stork, G.; Danheiser, R. L. J. Org. Chem. 1973, 38, 1775-1776. (b) Kende, A. S.; Fludzinski, P. Org. Synth. 1985, 64, 68-72. Carini, D. J. Personal communication, Jan. 2009. (a) Danheiser, R. L.; Carini, D. J. J. Org. Chem. 1980, 45, 3925-3927. (b) Danheiser, R. L.; Carini, D. J.; Kwasigroch, C. A. J. Org. Chem. 1986, 51, 3870-3878. Jellal, A.; Santelli, M. Tetrahedron Lett. 1980,21,4487^1490. Danheiser, R. L.; Kwasigroch, C. A.; Tsai, Y.-M. J. Am. Chem. Soc. 1985, 107, 7233-7235. Danheiser, R. L.; Fink, D. M. Tetrahedron Lett. 1985, 26, 2513-2516. Becker, D. A.; Danheiser, R. L. J. Am. Chem. Soc. 1989, 111, 389-391. Evans, D. A.; Sweeney, Z. K.; Rovis, T.; Tedrow, J. S. J. Am. Chem. Soc. 2001, 123, 1209512096. Danheiser, R. L.; Stoner, E. J.; Koyama, H.; Yamashita, D. S.; Klade, C. A. J. Am. Chem. Soc. 1989,7/7,4407^1413. Daidouji, K.; Fuchibe, K.; Akiyama, T. Org. Lett. 2005, 7, 1051-1053. Danheiser, R. L.; Becker, D. A. Heterocycles 1987, 25, 277-281. Angle, S. R.; Arnaiz, D. O. Tetrahedron Lett. 1991, 32, 2327-2330. Yadav, V. K.; Sriramurthy, V. Org. Lett. 2004, 6,4495^498. Friese, J. C; Krause, S.; Schäfer, H. J. Tetrahedron Lett. 2002, 43, 2683-2685. (a) Asaoka, M.; Kosaka, T.; Itahana, H.; Takei, H. Chem. Lett. 1991, 1295-1298. (b) Kim, S. K.; Pak, S. J. Org. Chem. 1991, 56, 6829-6832. (c) Honda, T.; Ishige, H.; Nagase, H. J. Chem. Soc, Perkin Trans. 1 1994, 3305-3310.

Chapter 3 Five-Membered Carbocycles

3.2

93

D i e c k m a n n condensation

Noha S. Maklad 3.2.1

Description 0

u R l NaOEt pBn% C02R·,

0

Ri

é

λJ V

fi)n

The Dieckmann condensation is an intramolecular reaction by which cyclic ß-keto esters are formed using tethered di-esters under basic conditions.1^ The name derives from its originator, Walter Dieckmann, who first reported the reaction in 1894 and demonstrated the formation of ethyl ßketocyclopentanecarboxylate from ethyl adipate using sodium base and, in a similar fashion, the formation of ß-ketocyclohexanecarboxylate from ethyl pimelate.1 3.2.2

Historical Perspective

Born in Hamburg, Germany on October 8, 1869, Walter Dieckmann studied at the University of Munich and became an assistant to Adolf von Baeyer. He died on January 12, 1925. Dieckmann initiated his work on this condensation reaction at Baeyer's urging. The work intended to test the adaptability of Baeyer's voltage theory in forming 5- and 6-membered rings.1'4 Although the Dieckmann condensation can be used to produce 4-membered cyclic ßketo esters, the reaction yield is usually low. On the other hand, the Dieckmann condensation is a reliable method to form 5- and 6- membered ßketo esters, and a subsequent de-carboxylation can form the cyclo-keto analogues.1 Larger rings can be formed under dilute conditions, in which case the yield depends on the size of the ring to be formed.5 The Dieckmann condensation has been used not only for the synthesis of alicyclic but also heterocyclic ß-keto esters. 3.2.3

Mechanism

There are few mechanistic studies for the Dieckmann condensation.6 10 The reaction can simply be described as an intramolecular Claisen condensation and hence entirely reversible. The summation of the consensus for its mechanism is as follows: the reaction is initiated by anion formation through the abstraction of the most acidic proton on the α-carbon to one of the di-

Name Reactions for Carbocyclic Ring Formations

94

esters (note that there must be at least one α-methylene hydrogen to the diesters), forming an enolate resonance.6 This is followed by the C-C bond formation by the attack of the enolate on the carbonyl of the second ester entity and the release of the alkoxylate ion from the tetrahedral transition state (B). The C-C bond formation (i.e., the ring formation) step was proven to be the rate-determining step of the reaction, using 14C isotope experiments conducted and published by Carrick and Fry in 1955.7 The alkoxylate ion then proceeds to remove a proton from the methylene of the keto ester (C) to give the enolate (D). The final product can be separated after an acidic workup. The reaction follows first-order kinetic when conducted in alcohol (protic solvent) and when a large excess of the base (e.g., Na ethoxide) is used; this is due to the formation of stable enolate anion of the end product that drives the reaction forward. On the other hand, the reaction is bimolecular in the presence of any solvent of a low di-electric constant (aprotic solvent) and excess base. In the latter case, the reaction rate increases in magnitude with the increase of the strength of the base used, as seen in the following order of bases: MeCT < EtO~ ~ Pr"0~
Q

.r\ f~~^ RO

POOR

-

-

Y^OW

^

>

"

^Λθ^° (B)

One of the obstacles to designing the ring closure of the Dieckmann condensation is the regioselective control of the reaction. Although the condensation usually occurs in the direction that forms the most stable enolate, there are at least two possible products competing for formation if the starting diester is unsymmetrical. Naturally, if one of the α-carbons to the

Chapter 3 Five-Membered Carbocycles

95

di-esters is di-substituted, then there is only one way for the ring to close, provided that the other direction would form a stable enolate. Substrates with α-substitution will prefer ring closure where the least hindered enolate is formed, and similarly for ß-substituted di-esters, anion formation (and hence the cyclization) would steer away from the substituted methylene group. A simple example for the latter is the synthesis of compound 2 using sodium alkoxide from starting material 1 in 80% yield.5

X

COOEt COOEt

NaOEt EtOH, 80%

-Ur

The use of labile auxiliaries to replace one ester moiety was also proven to be a useful strategy for regioselective control of the ring closure as shown by Kondo and coworkers in the case of forming carbapenem 4 or as shown by Déziel and coworkers in the case of forming carbapenem 6.11'12 In the first case, the auxiliary dihydrobenzoxazone was used to give the product using TMSCl-promoted cyclization in 82% yield. It is worth noting that the yield of the reaction decreased to 18% in the absence of TMSCl. In the latter reaction, the acyl auxiliary 4,4-dimethyl-l,3-oxazolidine-2-thione was used to form the product 6 using LiHMDS or NaHMDS in THF at -78 °C in 2 min.

1.NaN(TMS)2(2.5eq) 2. TMSCl (1.3 eq) 3. CIPO(OPh)2 THF, -35 °C, 82%

OTBS ^J, /^-OPO(OPh)2 C0 2

Name Reactions for Carbocyclic Ring Formations

96

NaHMDS (2 eq) THF, -78 °C, 60 %

/^~0 5 σ

6

C02Et

The use of JV-methoxy-7V-methylamides auxiliary (Weinreb amide) to replace one of the di-esters has also been used for chemoselective control. The direction of cychzation depends on the kind of base used. The base first removes the proton at the α-position of either the ester side or of the amide side. In the case of KO/-Bu, if the deprotonation occurs at α-position to the ester then intermediate 10 is formed. Because potassium's poor chelating ability is combined with the fact that the amide is a poor leaving group, the intermediate reverts back to 7, and the cychzation goes to form the isomer 8. On the other hand, the use of LDA or LiHMDS would produce the stable Licomplex 11 and directs the cychzation to form compound 9. OMe

°iN ^

Eto

x MC>V_ 12

J

1

O^OEtA

.OMe

7

11

Regio-control for this condensation can also be achieved using sterics. Although six-membered rings are beyond the scope of this chapter, it is important to mention some examples where the size of the esters used can determine the direction of cychzation: for example, the use of a bulky ester such as phenyl esters as exemplified in the synthesis of the carbacephem antibiotic of structure 14. The ring closure of the ß-lactam di-ester 13, using either potassium tór/-butoxide or lithium hexamethyldisilazide in tetrahydrofuran at -78 °C, steers the ring closure to only one regioisomer, and the de-protonation occurs a- to the bulky ester.14

Chapter 3 Five-Membered Carbocycles

97

ROCHN LiHMDS J—N 0

) R'OOC 13

CÄXH

THF, -78 °C

O^OR'

77%

R= CBZ, X = PMB Yiled R= CBX, X = PNB Yield = 48%

14

Similarly, if one of the di-esters is replaced by JV,iV-dibenzoyl carbonamide, as in the case of compound 16 (synthesized from compound 15 in 4 steps), the cyclization is regioselective and gives the corresponding carbacephem 17 in the presence of sodium bis(trimethylsilyl)amide as the base.15

Ph

\ Jrίν^

Ph^^ 0

15

^C02H

PhOC

N-COPh

NH2 16 NaN(SiMe3)2/THF/Et20 -60 °C to -50 °C, 20 min.

3.2.4

N

I

Γ

|

Cf

N

T^OH

17

C02Me

Standard Method, Variations and Improvements

To form the 1,3-diketoesters, the starting diester condenses in the presence of a base. The standard procedure for the reaction is to use metal alkoxides of Na, Li, or Mg in the corresponding alcoholic solvent (ethanol, methanol, tbutanol etc.) or sodium metal in aprotic solvent such as toluene or xylene. Other bases and solvent combinations are also used such as NaH, or KH in DMF, LiHMDS, KHMDS, or LDA in THF, alkali carbonates, and alkali hydroxides.5'18'19 Di-thiol ester version for the Dieckmann-type condensation.20 The original Dieckmann condensation conditions require high temperatures and prolonged reaction time, and the decarboxylation that follows to form the corresponding cyclic-keto analogue requires harsh acidic or basic conditions.

Name Reactions for Carbocyclic Ring Formations

98

Liu et al. in 1979 reported a dithiol version of the Dieckmann condensation. The simple variation offers milder conditions and shorter reaction time. The reaction starts with the appropriate tethered dithiol esters, and under a basic condition the corresponding cyclic ß-keto thiol esters are formed in a good yield at room temperature. An example of this variation is the synthesis of Sethyl-2-cyclopentaneonecarboxythiolate (19) in 91% yield from di-S-ethyl hexanedithiolate (18) using sodium hydride in the presence of a catalytic amount of ethanethiol in dimethoxyethane (DME). The thiol ester group can then be easily removed to give the corresponding cyclopentanone using an excess of Raney nickel under neutral condition. Although this reaction has not received much attention, it was the inspiration for the mono-thiol version of the Dieckamnn condensation, a variation that allowed reasonable chemoselective control of the ring formation. ^^~~„~ r COSEt kv .cosEt 18

1.3 eq. NaH, cat. ethanedithiol ^Μ. DME,rt r>..,- „ r \ V-SEt _ *■ * ^ y thenl NHCI, 91% 19

~ kl . Ra Ni „ * EtOH, rt

Mono-thiol ester version of the Dieckmann-type condensation21 The importance of controlling the direction of ring closure for the unsymmetrical di-ester condensation has prompted researchers to introduce different chemoselective methods for this reaction. The mono-thiol version of the condensation was first developed for that particular purpose by Yamada, Hosaka, and co-workers in 1981. An example is the ring formation of compounds 22. The ring closure occurs using an appropriate base such as lithium diispropylamide (LDA) in dry THF at -30 °C in the case of X = CH2 or sodium hydride at room temperature in case of X = N (or S) to form the corresponding carbocyclic or heterocyclic rings 22a-c in 74-77% yields.

COR-, X^COR2

base

21 a-c a. X= CH2, Ri= SEt, R2= OEt b. X=S, Ri = SEt, R2=OEt c. X= NC02Et, R-,= SEt, R2= OEt

4

O N-^\

LV-R3 L^ x 22 a-c

a. X= CH2, R3= C02Et, R4= H b. X= CH2, R3= C02Et, R4= H c. X= NC02Et, R3= C02Et, R4= H

Chapter 3 Five-Membered Carbocycles

99

Ring closure is pushed to the opposite direction to form the corresponding thioesters 23a,b in 68-70% yields using the Lewis acid (AICI3) in the presence of an Et3N base. Another combination of Lewis acid and base is also used to promote this kind of regioselectivity such as MgCb, MgBr2, and Sn(OS02CF3)2 in the presence of Et3N or TV-ethylpiperidine in suitable solvents such as CH2CI2, CH3CN, or a combination of both. This work was developed by Nagao, Tamai, and co-workers in 1995.22 z\

X COR, k^COR2

AICI3 (2.4 mol eq) Et3N (2.4 mol eq) CH2CI2, 0 °C

21a,d a. X= CH2, d. X= S,

0

ò

R-|= SEt, R2= OEt R!= SEt, R2= OEt

/~R3

I

^23a,d x

a. X= CH2, b. X= CH2,

R3= COSEt, R4= H 45 min, 70% R3= COSEt, R4= H 15 min, 68%

Ti-Dieckmann condensation In 1989 Tanabe and coworkers published a new variation of the condensation where the Lewis acid dichloro-bis(trifluoromethanesulfonato) titanium(IV) TiCl2(OTf)2 is used to promote the condensation under mild basic condition (Et3N for example). In 1997, the group published another paper showing an improvement on the condensation by using TiCU and BU3N amine (1:1.2) molar ratios with a catalytic amount of TiCL^OTfh or a catalytic amount of TMSOTf (0.05 equiv). Although this variation can produce the ß-ketoesters in reasonable yields, the reaction needs to be at room temperature or heated up to 60 °C to reach completion. In 1999, the group published yet another improvement to perform the reaction at a lower temperature by using TMSC1 in catalytic amounts. The use of T1CI4/BU3N with TMSC1 (0.05 equiv) allowed the reaction to be run at -78 °C, as seen in the synthesis of 25 from dimethyl adipate (24) shown below. /-.

L^/C02Me 24

T1CI4/BU3N

O C02Me

TMSCI (0.05 equiv) CH2CI2,-78 °C, 2 h

25

95%

Later, Tanabe and co-workers reported a dehydration version of the Ti-Dieckmann condensation. The reaction can be considered as a

100

Name Reactions for Carbocyclic Ring Formations

combination of the monothiol and Ti-Dieckmann condensations. The cyclization proceeds in the presence of a mild base to produce dehydration adducts that carry the thiol moiety in the end product. Difference from the original Ti-Dieckmann exists in the stoicheometry of the T1CI4 and the base, as well as with the kind of base used. Regioselective synthesis of 4,5dihydrothiophene-2-carboxylates and methyl thiophene-2-carboxylate could be used as an example of such variation. In this example, there are two possible products, and selectivity can be reached between the formation of the two adducts readily. Subjecting 26 to 2.2 eq. (sec-BuhNH, and 2.4 equiv of T1CI4 gives the vinyl sulfides adducts 27. In contrast, the use of 5 equiv T1CI4 and 5.2 equiv Et3N from -50 to -45 °C gives the totally unsaturated adducts 28 in good 82-87% yields.23^29 COSR C02Me

TiCI4 -base

s^

CH2CI2, 30 min

26

S R

s^SR

C02Me

C02Me

27

28

Tanabe et al. proposed mechanism for the dehydration-type TiDieckmann condensation and thiophene formation is shown below.

Gr'TiCU

COSR 2 T1CI4-2 amine C02Me

S>

s(fSR __ s ^ ; S R

-amine. HCI

26

ClaTi

-SR \ C02Me 27

TiCI4-Et3N

0T1CI3

jl OJOMe

OMe

C02Me

-Et3N.HCI

Chapter 3 Five-Membered Carbocycles

101

SC02Me 28

The Dieckmann condensation was reported once in the literature to proceed in solvent-free conditions. Toda, Higa and coworkers showed the condensation of adipate (24) and pimelate di-esters (34) to give the corresponding cyclized products using powdered base such as (BuONa, EtOK, and EtONa). The reaction proceeds with the solid di-esters that have been mixed by using a mortar and a pestle with the powdered base for 10 min, and the mixture was then kept in a desiccator for 60 min and then neutralized with p-TSOH-r^O to give the condensed product in 60-82% yields.30 /

C02Me

(CHA' \ ^ C 0 M e 2 24; n 34; n

3.2.5

1 2

Base

C02Me 25; n = 1 35; n = 2

Synthetic Utility

General Utility The Dieckmann condensation's main utility is the synthesis of 5- and 6memebered carbocyclic and heterocyclic ß-ketoesters. The cyclization requires tethered di-esters and base to proceed. As discussed before, different variations have resulted in a fine-tuning of the condensation reaction and have allowed it to serve as a wider base for versatile 5- and 6-membered rings. Regioselective techniques were developed to direct the cyclization of unsymmetrical esters. An interesting example of this aspect of the Dieckmann condensation is the synthesis of lß-methylcarbapenems by Tanabe and co-workers, lß-methylcarbapenems is a structure that exists in potent and broad antibacterial compounds, such as meropenem and biapenem, which renders it synthetically interesting for the synthesis of some close analogues 30a-d. Thioesters 29 was subjected to cyclization under dehydration type Ti-Dieckmann condensation conditions; 3.0 equivalents of the TiCU and 3.3 equivalents of the base BU3N were used to give the vinyl

102

Name Reactions for Carbocyclic Ring Formations

thiol products where the 4 stereogenic centers were retained, and the cyclization proceeded in good yields (the dehydration reaction is thought to go by a mechanism similar to that of synthesis of compounds 27).29

,_,, , H v —NH

NMe2

i

N

Biapenem

Meropenem

TiCI4 (3 equiv.) Bu3N (3.3 equiv) CH2CI2, -45 °C to -40 °C, 65-81% 30a-d R=

—CH 2 Ph,

—(CH 2 ) 7 CH 3

30a; 72%

30b; 65% CONMe2 N-C0 2

30c; 81%

H

^5"

30d; 72%

The Dieckmann condensation plays an important role in medicinal chemistry because it provides an easy access to 5-memebered rings. Rapoport asymmetric synthesis of the carbocyclic nucleosides' precursor 33 and 38 is a good example; carbocyclic nucleosides are good nucleosides' isosteres. For the synthesis of 33, the imidazolyl starting material 27 undergoes Dieckmann condensation using KHMDS to give ß-keto ester 28 in a 97% yield and a 3:1 diastereomeric mixture. The cyclized ß-keto ester 28 undergoes various transformations to give the lithium carboxylate 29. The carboxylate is then converted to the eis- bicyclic lactam 30 using NaOAc and refluxing in Ac 2 0, which is then hydrolyzed with AcOH and 6 M HCl of ratio 2:1. The acid formed is then converted to its methyl ester and reduced to give the intended cis-amino alcohol 33, all in good yields. The amino alcohol is an important precursor for subsequent carbocyclic nucleosides.31

Chapter 3 Five-Membered Carbocycles

MeO NHPf 27

Li02C

xy

0

KHMDS 97%

Ac 2 0, 97%

XT

NPf \

AcOH/HCI

/ 30

29

R02C

/

\ 28

^

NaOAc

NHPf

MeO

103

NH2.HCI

1. LiAIH4 2. HCI, 75%

NH2.HCI

_^HO' 33

R = H 31 MeOH, HCI( V R = Me 32

The Rapoport regioselective synthesis of the carbocyclic precursor 38 is another example. The synthesis starts with the reaction of the di-ester 34 with lithium 2,2,6,6-tetramethylpiperidine (LiTMP) to give 35 almost exclusively as eis and trans isomers. The keto-ester formed is reduced using NaBrL; to give a mixture of 4 diastereomers; the mixture is mesylated and subjected to elimination conditions using potassium teri-butoxide to give 36a in 69% yield; the ester is then reduced using LÌAIH4 to give the aminocyclopentenol 37, which undergoes a sequence of transformations to give 39, a carbocyclic analogue of pentostatin (a natural product of microbial origin with potent anticancer activity).32 „C02Me

Me0 2 C NHPf

1. LiTMP, THF, -78 °C 2. NaBH4, MeOH/THF Me02C

34

LMsCI, Pyr, THF, 0 °C

HN

„Pf

/X^c02Me

2. KOf-Bu, THF, 0 °C 3% from 36b

Name Reactions for Carbocyclic Ring Formations

104

36a

LiAIH4,THF

1.9-BBN, THF

». 2. 30% H202, THF 1 M NaOH 90%

In 1999, Shindo and Sato reported an interesting one-pot tandem [2 + 2]-cycloaddition-Dieckmann condensation. The condensation is a unique approach for the synthesis of functionalized 5- and 6-membered rings. The reaction proceeds by first treating the ynolate anions of structure 41, which is formed readily in situ from its corresponding α,α-dibromo esters with 4 equiv of tert-Buhi at -78 °C. The reaction is warmed up to 0 °C, followed by the addition of γ-keto-esters of structure 40 in THF, after which the temperature is then lowered to -78 °C, and the reaction then proceeds at that temperature. After workup and with no purification, acid-catalyzed decarboxylation in benzene follows to give compounds of structure 42 in good yields. R-

C02Et

P° R

40

41

-OLi

,OLi

Et02C

*· condensation

hR

decarboxylation

Dieckmann

42

Solid-phase synthesis can provide an attractive direction for the regioselective control of the condensation. In 1970s and 1980s, Rapoport and Crowley pioneered the regioselective Dieckmann condensation for the 6membered ring. Synthesis, of the 5-membered ring using solid-phase Dieckmann condensation conditions (as exemplified by synthesis of tetramic acids) was explored latter by different groups. 6~38 Tetramic acids are important building blocks in natural products and represent potentially good binding motifs for biological targets such as the asymmetric solid phase synthesis of benzothiadiazine-substituted tetramic

Chapter 3 Five-Membered Carbocycles

105

acids of structure 46, which are potentially potent inhibitiors of hepatitis C virus RNA-dependent RNA polymerase. The tetramic acid final product is formed in two steps by first the acylation of the resin bound enantiomerically pure Fmoc-protected L-amino acid (43) with the acid 44 to give 45. The product then undergoes Dieckmann condensation using KO/-Bu in THF//BuOH (2 : 1) or TEA in CH2CI2. The choice of base is important to minimize racemization. The cyclization and the concomitant cleavage from the resin occur at room temperature in 15 mm.

O.

DIC, HOAT, 5 eq DMF, 3 d

H Pol' R-ι

39

POI-

V

R2

43

R1

NT

H0 2 C

I

-0- Y : r R2 45

N H 5eq

44 KO-i-Bu, 2.5 eq THF: i-BuOH

Applications in the total synthesis of natural products The Dieckmann condensation is implemented in numerous natural product syntheses. Shindo and Shishido use their [2 + 2] tandem cycloadditonDieckmann condensation in the construction of the cyclopentenone unit in The condensation drives the the total synthesis of cucumin E.40 transformation of compound 47 first to the intermediate 49 using lithium ynolate 48 (3 equiv) in THF at -20 °C for 1 h, which is then followed by decarboxylation of the adduct by refluxing in toluene for 13 hin the presence of a catalytic amount of silica gel to give cucumin E in 54% yield in two steps. O H

0 C0 2 Et Me

=

OLi

48 Ö

47

THF, - 2 0 °C

106

Name Reactions for Carbocyclic Ring Formations

Silica gel (cat.) »» toluene,reflux 54% for two steps 50

cucumin E

Synthesis of physarorubinic acid, which is a polyenoyltetramic acid plasmodial pigment, is another example. The synthesis uses a LaceyDieckmann cyclization starting with ester 51, followed by deprotection to give physarorubinic acid (52) in 78% yield for the two steps.41'42 TBSO

O'Bu "I.NaOMe, MeOH 25 °C, 2 min 2. CF 3 C0 2 H:H 2 0 9:1 10 min

TBSO-

Tetronic acids (4-hydroxy-2(5//)-furanones) are also an example of 5membered rings, and they are compounds of potential activity as antibiotics, antiviral and neoplastic agents. The base-promoted Dieckmann condensation is one of the desired methods to produce 3-acyl-tetronic acids. An example is the intramolecular tetrabutylammonium fluoride-promoted Dieckmann cyclization of 53 to give tetronasin (54) in 72% yield. OMe 1.TBAF 2. HF, CH 3 CN NaHC0 3 , 72 % cr

0

53

Chapter 3 Five-Membered Carbocycles

,x

107

'ΌΜβ

3.2.6 Experimental Dieckmann condensation of ethyl adipate: 2-Carbethoxycyclopentanone (24) O OEt C02Et

1. Na, toluene 100-115°C 2. aq. HOAc

EtO

O V^

t\J

O

A three-necked, round-bottom flask is fitted with a mercury sealed mechanical stirrer, a 250-mL dropping funnel, and a reflux condenser protected from air by means of calcium chloride tube. In the flask are placed 23 g sodium and 250 mL toluene. The stirrer is started, and 202 g ethyl adipate is added from the dropping funnel at such a rate that the addition is complete in 2 h. The reaction usually starts immediately on addition and for about 5 h longer. Dry toluene is added through condenser from time to time to keep the reaction mixture fluid enough for efficient stirring. Between 750 mL and 1 L of toluene is added in this manner. The reaction mixture is cooled in an ice bath and slowly poured into 1 L 10% acetic acid cooled to 0 °C (ice-salt mixture). The toluene layer is separated, washed once with water, twice with cooled 7% Na2CC>3 solution, and again with water. The toluene is removed by distillation at ordinary pressure, and the residue is distilled under reduced pressure. The yield is 115-127 g (74-81%). 3.2.7 References 1. 2. 3. 4. 5.

Dieckmann, W. Ber. 1894, 2 7, 102-103. (a) Dieckmann, W. Ber. 1900, 33, 2670-2684. (b) Dieckmann, W.; Groeneveld, A. Ber. 1900, 33, 595-605. (a) Dieckmann, W. Chem. Zentr. 1900, 2, 892-893. (b) Dieckmann, W. Chem. Zentr. 1900, 1, 715-716. (a) Dieckmann, W. Liebigs Ann. 1901, 27-109. (b) Dieckmann.W. Chem. Zentr. 1901, 2, 630-636. [R] Schaefer, J. P.; Bloomfield, J. J. Org. React. Wiley & Sons: New York, 1967,15, 1-203.

108 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18. 19. 20. 21. 22. 23. 24. 25. 26. 27. 28. 29. 30. 31. 32. 33. 34. 35. 36. 37. 38. 39. 40. 41. 42. 43. 44.

Name Reactions for Carbocyclic Ring Formations Reed, R. I.; Thornely, M. B. J. Chem. Soc. 1954, 78, 2148-2150. Carrick, W. L.; Fry, A. J. Am. Chem. Soc. 1955, 77, 4381^1387. Burinsky, D. J.; Cooks, R. G. J. Org.Chem. 1982, 47, 4864-^869. Hauser C. R.; Renfrew, W.B.J.Am. Chem. Soc. 1937, 59, 1823-1826. Nishimura, T.; Sunagawa, M.; Okajima, T.; Fukazawa, Y. Tetrahedron Lett. 1997, 38, 70637066. Déziel, R.; Favreau, D. Tetrahedron Lett. 1989,30, 1345-1348. Kondo, K.; Seki, M.; Kuroda, T.; Yamanaka, T.; Iwasaki, T. J. Org. Chem. 1997, 62, 28772884. Sibi, M. P.; Christensen, J. W.; Kim, S.; Eggen, F.; Stessman, C; Oien, L. Tetrahedron Lett. 1995,56,6209-6212. Jackson, B. G.; Gardner, J. P.; Heath, P. C. Tetrahedron Lett. 33, 6317-6320. Neyer, G.; Ugi. I. Synthesis 1991, 9, 743-744. Rapoport, H; Crowley, J. J. Am. Chem. Soc. 1970, 92, 6363-6365. Crowley, J. I.; Rapoport, H. J. Org. Chem. 1980, 45, 3215-3227. Pàtek, M.; Hampl. F. Collect. Czech. Chem. Commun. 1989, 54, 3267-3277. Svoboda, J.; Nie, M.; Palecek, J. Collect. Czech. Chem. Commun. 1992, 58, 592-599. Liu, H.; Lai, H. K. Tetrahedron Lett. 1979,20, 1193-1196. Yamada, Y.; Ishii, T.; Kimura, M.; Hosaka, K. Tetrahedron Lett. 1981, 22, 1353-1354. Tamai, S.; Ushirogochi, H.; Sano, S.; Nagao, Y. Chem. Lett. 1995,295-296. Tanabe, Y. Bull. Chem. Soc. Jpn. 1989, 62, 1917-1924. Yoshida, Y; Hayashi, R.; Sumibara, H.; Tanabe, Y. Tetrahedron Lett. 1997, 38, 8727-8730. Yoshida, Y; Matsumoto, N.; Hamasaki, R.; Tanabe, Y. Tetrahedron Lett. 1999, 40, 42274230. Tanabe, Y. Chem. Commun. 2001, 1674-1675. Tanabe, Y.; Makita, A.; Funakoshi, S.; Hamasaki, R.; Kawakusu, T. Adv. Synth. Catal. 2002, 344, 507-510. Nagase, R.; Gotoh, H.; Katayama, M.; Manta, N.; Tanabe, Y. Heterocycles 2007, 72, 697708. (a) Tanabe, Y.; Manta, N.; Nagase, R.; Misaki, T.; Nishii, M.; Sunagawa, M. Adv. Synth. Catal. 2003, 345, 967-970. (b) Iida, A.; Okazaki, H.; Misaki, M.; Sunagawa, M.; Sasaki, A.; Tanabe, Y. J. Org. Chem. 2006, 71, 5380-5383. Toda, F.; Suzuki, T.; Higa, S. J. Chem. Soc, Perkin Trans. 1,1998, 3521-3522. Bergmeier, S. C; Cobas, A. A.; Rapoport, H. J. Org. Chem. 1993, 58, 2369-2376. Ho, J. Z.; Mohareb, R. M.; Ahn, J. H.; Sim, T. B.; Rapoport, H. J. Org. Chem. 2003, 68, 109-114. Shindo, M.; Sato, Y.; Shishido, K. J. Am. Chem. Soc. 1999,121,6507-6508. Rapoport, H.; Crowley, J. I. J. Am. Chem. Soc. 1970, 92, 6363-6365. Crowley, J. I.; Rapoport, H. J. Org. Chem. 1980, 45, 3215-3217. Kulkarni, B. A.; Ganesan, A. Tetrahedron Lett. 1998,39,4369^1372. Weber, L.; Iaiza, P.; Biringer, G.; Barbier, P. Synlett 1998, 1156-1158. Romoff, T. T.; Ma, L.; Wang, Y.; Campbell, D. A. Synlett 1998, 1341-1342. Evans, K. A.; Chai, D.; Graybill, T. L.; Burton, G.; Sarisky, R. T.; Lin-Goerke, J.; Johnston, V. K.; Rivero, R. A. Bioorg. Med. Chem. Lett. 2006,16, 2205-2208. Shindo, M.; Sato, Y.; Shishido, K. Tetrahedron Lett. 2002, 43, 5039-5041. Dixon, D. J.; Ley, S.V.; Longbottom, D. A. J. Chem. Soc, Perkin Trans. 1, 1999, 22312232. Lacey, R. N. J. Chem. Soc. 1954, 850-854. Tejedor, D.; Garcia-Tellado, F. Org. Prep. Proced. Int. 2004, 36, 35-59. Pinkney, P. S. Org. Synth. 1937,17, 30.

Chapter 3 Five-Membered Carbocycles

3.3

109

Favorskii Rearrangement

Brian Goess 3.3.1

Description

When oc-haloketones are treated with a nucleophilic base in protic or ethereal solvents, a transformation known as the Favorskii rearrangement occurs to yield carboxylic acid derivatives.1 Depending on the identity of the incorporated base the final product will be a carboxylic acid, ester, or amide. Cyclic oc-haloketones undergo a ring contraction during the course of the rearrangement. O

O

R 2 - H - ^

/

R t

Y

A

R2

Nu+HX

X = C..Br.l.OH.OT8

Nu="OH, O R , HNR2

The rearrangement is general for a wide range of oc-haloketones and some oc-haloketimines; however, yields vary widely due to competitive side reactions that are highly dependent on both solvent and the structures of the substrate and base.2 When unsymmetrical oc-haloketones are used, an unsymmetrical cyclopropanone intermediate is generated that fragments regioselectively to generate one of two possible constitutional isomers. When cc-chiral-haloketones are used, the rearrangement occurs with high stereoselectivity if reaction conditions are chosen such that competitive dissociative mechanisms are disfavored. 3.3.2

Historical Perspective

Reactivity between cc,cc-dihaloketones and bases was initially described in 1890 by Cloez, who determined that treatment of 1 under saponifying conditions led to formation of α,β-unsaturated acid 2.3 O Br^ A Br 1

.C0 2 Et CH, ^3

COOH

KOH H2

°

H 0 0 C

CH

3

2

Indeed, 4 years later Favorskii described an analogous transformation on a dichloroketone4 as part his ongoing investigations into the reactivity of

110

Name Reactions for Carbocyclic Ring Formations

halogenated carbonyls. rearrangements.

H3C

CI

/\

These reactions are now known as Favorskii

CI

*■ HaC

CH 3

One of the most common early uses of the Favorskii rearrangement was for the preparation of highly branched carboxylic acids and esters. For instance, when 3-bromo-3-methyl-2-butanone is treated with sodium isopropoxide at room temperature, isopropyl trimethylacetate is generated in 64% yield.5

H3C ^ r

ether 64%

M

3^ £ Η

3

Yields and reaction rates tend to increase with increasing alkyl substitution on the carbon bearing the halide-leaving group due to diminished competition from side reactions such as direct nucleophilic substitution by the base. Other competing reaction products that have been observed include epoxyethers, oc-epoxyketals, and α,β-unsaturated ketones. The Favorskii rearrangement can be highly stereoselective, a finding that has greatly expanded its synthetic utility. When oc-haloketone 3 is treated with base in 1,2-dimethoxyethane, ester 4 is formed diastereoselectively.6 Both this and the preceding reaction exemplify another important feature of the Favorskii rearrangement that has been repeatedly demonstrated over time: In general the reaction is highly regioselective when unsymmetrical ketones are used and favors formation of products derived from the most stable (usually the least substituted) of two possible carbanionic intermediates, although steric factors may also play a role in determining regioselectivity.2d

NaOCH3

(H3COCH2)2 88 %

CH3 ^ - f .C02CH3

\ ^ Λ ' 'Η CH

3

Chapter 3 Five-Membered Carbocycles

111

More recent work on the Favorskii rearrangement has focused on testing the ability of increasingly complex substrates to participate in Favorskii and related rearrangements. Efforts have also been directed at determining how reaction conditions affect the precise mechanism of Favorskii rearrangements. Both of these aspects of the Favorskii rearrangement will be discussed in subsequent sections. 3.3.3

Mechanism

The canonical formulation of the mechanism of the Favorskii rearrangement involves initial deprotonation of the cc-carbon to generate an enolate, intramolecular displacement of the leaving group on the oc'-carbon by the enolate to generate a cyclopropanone, addition of a nucleophile to the cyclopropanone ketone followed by elimination to generate the more stable of two possible carbanions, and protonation to yield the rearranged carboxylic acid derivative.

^

Br

ή

H2

j

c H a

— H * C - A H 2 — H 3 C3T : S CH3 Cßr—■'

*0!} OCH3 V

A)

il "

=

H3

°--AOCH3

II "

•0H2

H3C

VAOCH3 CH3

By 1950 five distinct mechanisms had been suggested to account for the formation of the major products of the Favorskii rearrangement. Four involved epoxide, ketene, enol, and carbene intermediates. A fifth mechanism related to the benzylic acid rearrangement was also proposed.7 Then, in 1951 Loftfield isolated two esters with identical isotope distributions at their a and ß carbons from treatment of a radiolabeled, cyclic oc-chloroketone with an alkoxide. These two products suggested a symmetrical intermediate, leading Loftfield to postulate the existence of a cyclopropanone along the reaction pathway.8 C0 2 R OR

C0 2 R

Name Reactions for Carbocyclic Ring Formations

112

The existence of a cyclopropanone intermediate was supported by subsequent experimental evidence, although in more polar media the presence of dipolar intermediates has also been inferred. 10 For example, when an aromatic a-bromoketone was treated with base in the presence of furan, the major product was a dipolar cycloaddition adduct which was isolated along with the Favorskii rearrangement product.11 Br

Br CH

O

3 Et3N

CF 3 CH 2 OH H3CO O

o

H3CO OCH,

27%

O H 3 CO" y OCH 3

F3C

H3CO OCH

The strained geometry required to achieve good orbital overlap in an intramolecular cyclopropanone formation between an enolate on an oc-carbon and an oc'-carbon bearing a halide-leaving group has led some to suggest an alternate pathway for cyclopropanone formation.12 In this pathway, halide departure immediately follows enolate formation to generate a delocalized zwitterion that undergoes an electrocyclization reaction to form the cyclopropanone. The Diels-Alder adduct above can be seen as proceeding through a similar zwitterionic intermediate. :OCH 3 Br

H

2

O

ci

O H 3 C^-

^J

=^ H3C^

For substrates that lack an enolizable α-proton or for which a cyclopropanone intermediate would be highly strained, Favorskii products can be formed instead through a semibenzylic (also known as quasiFavorskii) mechanistic pathway. This pathway involves addition of the base to the carbonyl followed by migration of an alkyl or aryl group with concomitant displacement of the halide.

Chapter 3 Five-Membered Carbocycles

113

O

H 3 CO : o ^

H,C

OCH 3 Lßr

CH,

H3C /^CHß H3C

:OCH 3

This mechanism is stereospecific and requires inversion at the carbon bearing the halide, a feature that was clearly demonstrated for a pair of conformationally locked substituted cyclohexane diastereomers.13 Substitution by-products were also observed. .OCH 3 3

xylenes 45% -OCH36

COOH

NaOH

k,

, 'Βιϊ

OCH 3 COOH

Λ11

NaOH

xylenes 45%

t BU

OCH3

The semibenzylic pathway was also used to prepare an intermediate in the synthesis of the core of tricycloclavulone.14 The rearrangement took place only on warming and was not successful when vinyllithium was used as the nucleophile. A similar approach was used sterpurene.15 H3C

Λ

\

V l ^ B r H3C 0

Li

/

THF, -78 °C

yp4rBr (F7-CH3 H3C

-30 °C 90%

In specific cases, evidence has been obtained that indicates subtle changes in reaction conditions, such as the identity of the base, can alter the preferred mechanism of product formation, leading to the suggestion that both the Favorskii and semibenzylic mechanisms may be simultaneously operative in some Favorskii rearrangements.215 A number of theoretical investigations of Favorskii rearrangement mechanisms have supported the above experimental observations.16 However, a recent study has elucidated a mechanistic variation whose activation energy for its rate-determining step (RDS; attack of the

Name Reactions for Carbocyclic Ring Formations

114

nucleophile on the cyclopropanone) is lower than that calculated for the canonical Favorskii and semibenzylic mechanisms.163 In this newly proposed mechanism, the halide ion generated in the cyclopropanone-forming step reacts first with the cyclopropanone to generate an acyl halide, which is subsequently esterified. Cl

NaOCH 3 CH3OH

3.3.4

»

CI

NaOCH 3

RDS

CH3OH

C0 2 CH 3

Variations, Improvements and Modifications

The canonical Favorskii rearrangement has seen few improvements or modifications, which is not surprising given the simplicity of the reagents used to effect the transformation. However, a number of variations have been developed to expand its scope, though none has received extensive investigation. The homo-Favorskii rearrangement occurs when enolizable ketones with ß-leaving groups are treated with base to yield rearranged products via a cyclobutanone intermediate. Successful examples of this transformation are rare due to competing elimination of the halide to yield an enone and the increased stability of cyclobutanones toward nucleophilic attack. However, in cases where the a' carbon is fully substituted, thus preventing premature elimination of the halide, homo-Favorskii rearrangements are possible. An early example of a base-catalyzed rearrangement of ß-dichloroketone 5 is illustrative. Though various mechanisms can be postulated, homo-Favorskii rearrangement via a cyclobutanone intermediate and subsequent elimination(s) leads to two of the observed reaction products obtained in approximately 25% combined yield. H3C CHCI2 -.0

H3C C0 2 H KOH H 2 0/dioxane 75 °C

KOH

/ ^ -

H3C C0 2 H

C l

^5/"

Transformations that use the initial steps of the homo-Favorskii rearrangement to prepare cyclobutanones are more common. When treated with base, ketone 6 generates cyclobutanone 8 via oxycyclopropane 7.18

115

Chapter 3 Five-Membered Carbocycles

H3CO,

Cyclobutanone precursors to the natural product kelosene were also 19 prepared under homo-Favorskii conditions. TsO

O

O KO'Bu /--'.|/

CH

"H I

3

'BuOH

H

3

C

H

CH3 +

H.„

95%

CH,

5:4

When a-chloroketimines are treated under Favorskii conditions, the corresponding rearranged imidates are generated. When potassium tbutoxide is used as the base, the imidates are converted into amides with concomitant elimination of isobutylene. N'

H,C

,'Pr

KO'Bu

CH3 CI

THF

64%

'Pr. ~NH -*- H,C CH,

,'Pr N'

'Prv *N y I CH3

CH3 CHH ? ' C

Name Reactions for Carbocyclic Ring Formations

116

One can generate cc-amino cyclopropanecarbonitriles in low yield when oc-chloroketimines are treated under Favorskii conditions with KCN as the base.21 The major products are oc-cyanoaziridines which arise from direct attack of cyanide on the imine. Evidence for the intermediacy of a cyclopropylidenamine along the pathway to formation of the minor product was obtained through trapping with an internal nucleophile.22 N' H3C H3C

KCN

H 'Pr-N

CH3OH reflux

H3CHaC

,'Pr CHo

CI

CN

'Pr I N HgC-^-CHa H3C

12%

CN

73%

Lewis acids can be used in place of Bransted bases to promote 23 Favorskii rearrangements. ZnCI 2 CH

Br

3

CH3OH, 115 °C 91%

H3C

CO2CH3

Finally, a Favorskii rearrangement has been proposed in the biosynthesis of the wailupemycins.24 The enzyme-catalyzed conversion of 9 to 11 can be envisioned to proceed through cyclopropanone intermediate 10. A Favorskii rearrangement has also been implicated in the biosynthesis of molecules related to okadaic acid.25

3.3.5

Synthetic Utility

Partial Favorskii rearrangements can sometimes be achieved under mild reaction conditions that prevent rupture of the cyclopropane ring. A series of bicyclic nitroxide spin probes were prepared in this manner.26

Chapter 3 Five-Membered Carbocycles

117 COCH3

O

H 3 CJ H3C

N

H C

COCH3

J L CH3

CH 3

Na

+

C02CH3 ΤΉ^50°Γ 81%

H H

\(

C0 2 CH 3

3°>0
3C

N O

CH

3

Highly strained structures can be prepared through the Favorskii methodology. For instance, a cis-t-butyl ethylene derivative was synthesized from an α,α'-dihaloketone on treatment with a "superbase," KOH in DMSO.27 t-Bu

t-Bu Br

Br

KOH/DMSO THF, 100°C 47%

COOH t-Bu

t-Bu

The Favorskii rearrangement has frequently been employed in ring contractions. For example, a Favorskii ring contraction was employed in the synthesis of the cage compound 12 en route to a hexacyclotetradecane,28 and of cage compound 14 en route to pentaprismane.29

reflux 88%

OTs

12

COOH KOH H 2 0, reflux 61%

A single cyclopropanone intermediate (16) gave rise to both observed rearrangement products obtained from treatment of 15 with DBU.30 In this case, the nucleophile is an internal enolate derived from deprotonation at C-l rather than an alkoxide anion. Products of attack of the regioisomeric enolate at C-2 were not observed.

118

Name Reactions for Carbocyclic Ring Formations CH3 O

CH3 O

CH3 O

CH3 O

Excellent stereoselectivities can be observed in Favorskii rearrangements. In the ring contraction of cyclohexanone 17, cyclopentane 18 was observed with greater than 10:1 dr, which prompted the authors to study a series of related compounds to determine the factors that control the stereoselectivity. Of compounds 19, 20, and 21, only 19 underwent a Favorskii rearrangement, also with high diastereoselectivity, leading the authors to conclude that a 3-oxy substituent is critical to the success of the rearrangement.31 CH3 THPO. ' γ ^ ^ γ ^

I

HaC'jt^f u o

I

CH3 NaOCH3 CH3OH 80%

- THPO··/

,—z"^

[

>^C0 2 CH 3 H3C

H3C

Favorskii ring contraction of ketone 22 followed by diastereoselective protonation led to ester 23, an intermediate in the synthesis of structures related to the guanacastepene core.3? In this case, an epoxide served as the leaving group. Favorskii rearrangements of various α,β-epoxyketones have been investigated.33

Chapter 3 Five-Membered Carbocycles

119 Η

1)NaOCH3 CH3OH reflux

3ζ OH

2) CH2N2 H3C02C· Et 2 0, 0 °C ΗHsC-4v 3°-\ /So/o 2 steps

H

23

An asymmetric Favorskii rearrangement has been developed that yields optically active oc-alkylamides from optically active cc-chloroketones. The reaction is presumed to proceed through a chelated intermediate containing a six-membered ring.3 O

O—NaH

H3C^CH3j^H3Ci^CH3_ CI

ο ^ ? ci Ar

is

O

82%, 85% e.e.

3.3.6

CH

H

» V

O

Ts-^^O

=0H

O

68%

Experimental

The examples presented illustrate two of the common ways Favorskii rearrangements are run. The first is a large scale Favorskii ring contraction. The second illustrates the use of the Favorskii rearrangement to form sterically congested carbon frameworks. Methyl cyclopentanecarboxylate35 C02CH3

A dry, 1 -L, three-necked, round-bottomed flask is equipped with an efficient stirrer, a spiral reflux condenser, and a dropping funnel, and all openings are protected by calcium chloride drying tubes. A suspension of 58 g (1.07 mol) of sodium methoxide in 330 mL anhydrous ether is added, and stirring is begun. To the stirred suspension is added dropwise a solution of 133 g (1 mol) 2-chlorocyclohexanone diluted with 30 mL dry ether. The exothermic

120

Name Reactions for Carbocyclic Ring Formations

reaction is regulated by the rate of addition of the chloroketone; about 40 min. is required for the addition. After the addition of the chloroketone is complete, the mixture is stirred and heated under reflux for 2 h and then cooled. Water is added until the salts are dissolved. The ether layer is separated, and the aqueous layer is saturated with sodium chloride. After extraction of the aqueous layer with two 50 mL portions of ether, the ethereal solutions are combined and washed successively with 100 mL portions of 5% hydrochloric acid, 5% aqueous sodium bicarbonate solution, and saturated sodium chloride solution. The ether solution is dried over magnesium sulfate, and the magnesium sulfate is removed by filtration and washed with ether. Removal of the ether by distillation at atmospheric pressure leaves the crude ester, which is distilled with fractionation at 70-73 °C/48 mm Hg. The yield of methyl cyclopentanecarboxylate is 72-78 g (56-61%). Compound 1429 O

é -é IOTS

13

COOH

14

Finely powdered 13 (1.3 g, 4 mmol) was added in portions to a preheated 20% aq. KOH solution (20 mL, 110 °C) and washed in with an additional 20 mL of base solution. The resulting mixture was refluxed rapidly with vigorous stirring for 5 h and became homogenous. Chloroform (50 mL) was added, the mixture was cooled to between 0 and 5 °C and then acidified with ice-cold 50 wt % sulfuric acid. The insoluble material formed was filtered through glass wool and extracted repeatedly with chloroform. The aqueous phase was extracted four times with chloroform (20 mL). The combined organic extracts were washed once with aqueous saturated ammonium sulfate (40 mL) and dried. After removal of solvent in vacuo 470 mg of a pale yellow solid remained. Purification via chromatography on silica gel (dichloromethane) gave 426 mg of 14 (61%). 3.3.7 1.

References [R] (a) Kende, A. S.; Org. React. 1960, //, 261-316. (b) Akhrem, A. A.; Ustynyuk, T. K.; Titov, Yu. A. Russ. Chem. Rev. (Engl. Trans.) 1970, 39, 732-746. (c) Rappe, C. In The Chemistry of the Carbon-Halogen Bond Part 2 (Patai, S. ed.) Wiley, London, 1973, pp 1084-1114. (d) Mann, J. Comp. Org. Syn. Trost, B. M.; Fleming, I., eds. Pergamon Press, Oxford, 1991, pp 839-859. (e) Guijarro, D.; Yus, M. Curr. Org. Chem. 2005, 9, 1713-1735.

Chapter 3 Five-Membered Carbocycles 2.

3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16.

17. 18. 19. 20. 21. 22. 23. 24. 25. 26. 27. 28. 29. 30. 31.

32. 33. 34. 35.

121

(a) House, H. O.; Frank, G. A. J. Org. Chem. 1965, 30, 2948-2956. (b) Warnhoff, E. W.; Wong, C. M.; Tai, W. T. J. Am. Chem. Soc. 1968, 514-515. (c) Loftfield, R. B.; Schaad, L. J. Am. Chem. Soc. 1954, 35-37. (d) Rappe, C; Knutsson, L.; Turro, N. J.; Gagosian, R. B. J. Am. Chem. Soc. 1970, 2032-2035. Cloéz, M. Ch. B. Soc. Chim. Fr. 1890, 602-605. Favorskii, A. E. J. Russ. Phys. Chem. Soc. 1894, 26, 559-603. Aston, J. G.; Greenburg, R. B. J. Am. Chem. Soc. 1940, 62, 2590-2595. House, H. O.; Gilmore, W. F. J. Am. Chem. Soc. 1961, 83, 3980-3985. These five possibilities are succinctly summarized and referenced to their original sources in Ref. 8. Loftfield, R. B. J. Am. Chem. Soc. 1951, 73, 4707-4714. Turro, N. J.; Hammond, W. B. J. Am. Chem. Soc. 1965, 87, 3258-3259. House, H. O.; Frank, G. A. J. Org. Chem. 1965, 30, 2948-2956. Mann, J.; Wilde, P. D.; Finch, M. W. Tetrahedron 1987, 43, 5431-5441. Aston, J. G.; Newkirk, J. D. J. Am. Chem. Soc. 1951, 73, 3900-3902. Baudry, D.; Bégué, J. P.; Charpentier-Morize, M. B. Soc. Chim. Fr. 1971, 1416-1424. Harmata, M.; Wacharasindhu, S. Org. Lett. 2005, 7, 2563-2565. Harmata, M.; Bohnert, G. J. Org. Lett. 2003, 5, 59-61. (a) Tsuchida, N.; Yamazaki, S.; Yamabe, S. J. Org. Biomol. Chem. 2008, 6, 3109-3117. (b) Hamblin, G. D.; Jimenez, R. P.; Sorensen, T. S. J. Org Chem. 2007, 72, 8033-8045. (c) Moliner, V.; Castillo, R.; Safont, V. S.; Oliva, M.; Bohn, S.; Tufion, I.; Andres, J. J. Am. Chem. Soc. 1997, 119, 1941-1947. (d) Castillo, R; Andres, J; Moliner, V. J. Phys. Chem. B. 2001, 105, 2453-2460. Wenkert, E.; Bakuzis, P.; Baumgarten, R. J.; Leicht, C. L.; Schenk, H. P. J. Am. Chem. Soc. 1971, 93, 3208-3216. Ceccherelli, P.; Curini, M.; Pellicciari, R.; Wenkert, E. J. Org. Chem. 1982, 47, 31723174. Zhang, L.; Koreeda, M. Org. Lett. 2002, 4, 3755-3758. De Kimpe, N.; Sulmon, P.; Moens, L.; Schamp, N.; Declercq, J.-P.; Van Meerssche, M. J. Org. Chem. 1986, 51, 3839-3848. De Kimpe, N.; Sulmon, P.; Verhé, R.; De Buyck, L.; Schamp, N. J. Org. Chem. 1983, 48, 4320^1326. De Kimpe, N.; Stanoeva, E.; Schamp, N. Tetrahedron Lett. 1988, 29, 589-592. Maiti, S. B.; Chaudhuri, S. R. R.; Chatterjee, A. Synthesis 1987, 806-809. Xiang, L.; Kalaitzis, J. A.; Moore, B. S. Proc. Nat. Acad. Sci. USA. 2004, 101, 1560915614. Wright, J. L. C; Hu, T.; McLachlan, J. L.; Needham, J.; Walter, J. A. J. Am. Chem. Soc. 1996,118, 8757-8758. Babic, A.; Peöar, S. Synlett 2008, 1155-1158. lonkin, A. S.; Marshall, W. J.; Fish, B. M. Org. Lett. 2008,10, 2303-2305. Takeshita, H.; Kawakami, H.; Ikeda, Y.; Mori, A. J. Org. Chem. 1994, 59, 6490-6492. Eaton, P. E.; Or, Y. S.; Branca, S. J.; Shankar, B. K. R. Tetrahedron 1986, 42, 16211631. Karimi, S.; Christodoulou, J.; Subramaniam, G. Synth. Commun. 2006, 36, 929-934. (a) Lee, E.; Yoon, C. H. J. Chem. Soc., Chem. Commun. 1994, 479^81. (b) Ley, S. V.; Antonello, A.; Balskus, E. P.; Booth, D. T.; Christensen, S. B. Cleator, E.; Gold, H.; Högenauer, K.; Hünger, U.; Myers, R. M.; Oliver, S. F.; Simic, O.; Smith, M. D.; Sohoel, H. Woolford, A. J. A. Proc. Nat. Acad. Sci. USA. 2004,101, 12073-12078. Srikrishna, A.; Dethe, D. H. Org. Lett. 2004, 6, 165-168. Mouk, R. W.; Patel, K. M.; Reusch, W. Tetrahedron 1975, 31, 13-19. Satoh, T.; Motohashi, S.; Kimura, S.; Tokutake, N.; Yamakawa, K. Tetrahedron Lett. 1993, 34, 4823^1826. Goheen, D. W.; Vaughan, W. R. Org. Synth. 1959, 39, 37-39.

122

Name Reactions for Carbocyclic Ring Formations

3.4

Nazarov Cyclization

Matthew J. Fuchter 3.4.1 Description The acid-catalyzed cyclization of divinyl ketones 1 (or their precursors) via pentadienyl cations 2, is known as the Nazarov cyclization.1 It is a commonly used method for the synthesis of cyclopentenones 3.

R2 R1

O 11

R3

Protic or Lewis acid (or light)

-H +

R2^/N^R3 R1

R4 3

The process can be catalyzed by either protic or Lewis acids; however, it is important to note, that stoichiometric (or even greater) quantities of promoter are often required.6 The reaction can also be initiated by irradiation, although this has mechanistic consequences (see Section 3.4.3). In general, any compound that affords a pentadienyl cation 2, or its equivalent, can be considered to undergo the Nazarov cyclization. Numerous substitution patterns are tolerated, although in some cases, regioisomeric double bond isomers may be obtained. Electron-donating substituents in the a and a' positions (R , R ), accelerate the reaction, whereas they retard the reaction in the ß and ß' positions (R1, R4). Judicious choice of substituents can polarize the conjugated system, accelerating the reaction and improving the regioselectivity of the cyclization. A notable example is the use of trialkylsilyl (or trialkylstannyl) groups in the ß and ß' positions (R1, R4), to ensure the controlled collapse of the cyclopentenylic cation (see Section 3.4.5.1). The use of chiral substituents can result in transfer of chirality, and limited examples exist for asymmetric catalysis (see Section 3.4.4.4). The cationic intermediates can be intercepted in alternative reaction pathways and results in 'interrupted' Nazarov processes (see Section 3.4.5.2). 3.4.2 Historical Perspective Nazarov's key work on the formation of cyclopentenones was preceded by a number of reports on analogous reaction pathways. For example in 1903, Vorländer and co-workers discovered that the treatment of dibenzylideneacetone 4 with concentrated sulfuric acid and acetic anhydride, followed by

Chapter 3 Five-Membered Carbocycles

123

hydrolysis with sodium hydroxide resulted in the formation of a cyclic ketol 5, the structure of which was unknown at the time.7 Indeed, there are several examples of reactions in the early literature which presumably follow analogous reaction pathways.8 O

Ph

Ph

1.H2S04, Ac 2 0 25-30 °C >2. NaOH

In the 1930s, Marvel and co-workers studied the acid-catalyzed hydration of dienynes,9'10 and it was this topic that Nazarov revisited in the 1940s and 1950s. He extensively studied this process and demonstrated the cyclization of the intermediate allyl vinyl ketones 7 to 2-cyclopentenones 8 in numerous cases.11-13 Mechanistic interpretation of the reaction remained unclear, however, until the studies of Braude and Coles in 1952.14 They demonstrated that the formation of 2-cyclopentenones actually proceeds via divinyl ketones (the allyl vinyl ketones in Nazarov's process isomerize in situ), with the intermediacy of carbocations. Thus the modern interpretation of the Nazarov cyclization was born: The acid-catalyzed closure of divinyl ketones 1 to 2-cyclopentenones 3. Me

3.4.3

H2SO4

Λ

HgS04 MeOhT

H20

O Me^/\

M 8

Me

Mechanism

For the protic acid catalyzed reaction, the cyclization commences with protonation of the divinyl ketone 9 and formation of a pentadienyl cation 10. An analogous process is operational in the case of Lewis acid-catalyzed reactions. The pentadienyl cation 10 then undergoes a 4π electrocyclic closure to give a cyclopentenylic cation 11. This cyclization is a peri cyclic reaction and is governed by the rules for conservation of orbital symmetry. Namely, this means the cyclization occurs stereospecifically in a conrotatory fashion, with predictable relative configurations of the substituents (i.e., the R groups in 11 are anti). Elimination of a proton, followed by tautomerization gives product 13.4

124

Name Reactions for Carbocyclic Ring Formations

Θ

H

4π conrotatory

+H+ R

.*.

11

ring-closure

R

R

9

^=^-

R

w

hv, 254nm PhH disrotatory

R R 14

AcOH H3PO4 50 °C conrotatory

Early attempts to verify the stereochemical predictions of orbital symmetry control were hampered by carbocation rearrangement reactions,15 such as Wagner-Meerwin shifts, although the very presence of these anomalous pathways is consistent with a cationic pathway. It is now well established that the Nazarov cyclization occurs via a pentadienyl cation 10, which has been spectroscopically observed,1 and shown to undergo facile cyclization to a cyclopentenylic cation l l . 1 5 The most convincing evidence for the involvement of a pericyclic reaction was the demonstration of complementary rotatory pathways for the cyclization of ketone 14.17 Acidcatalyzed thermal cyclization results in conrotatory ring closure and formation of product 16, whereas under photochemical conditions, disrotatory ring closure occurs, resulting the formation of product 15, in line with rules for conservation of orbital symmetry. This example also highlights

Chapter 3 Five-Membered Carbocycles

125

that the Nazarov cyclization can occur on irradiation, although it is important to realize that this results in an alternative rotatory pathway. The cationic reaction pathway also allows for predictable effects on differential substrate substitution.4 In the rate-limiting step, the distribution of charge (marked by *) changes from C(l), C(3) and C(5), in pentadienylic cation 18, to C(2) and C(4), in cyclopentenylic cation 19. Therefore, substituents that stabilize positive charge (electron-donating groups), accelerate the reaction in the α-position (R ), or decelerate the reaction in the ß-position (R1). Classically, under rather vigorous conditions, the reactions are under thermodynamic control and result in the formation of product 20, where the double bond occupies the most substituted position (Saytzeff s Rule). R2 R1

A N 17

ÌÌ11

«

+H+

*i

D2

> 1

J:©:l

R *

18

>-

-H +

R2

*

As well as the stereospecific conrotatory cyclization pathway, there is another stereochemical feature of the Nazarov cyclization, which arises from the duality of the allowed electrocyclization reaction.4 In the presence of a chiral remote substituent, substrate 21 can either undergo clockwise electrocyclization to give product 22 and/or 23, depending on the regiochemistry of the double bond, or counter-clockwise cyclization to give the corresponding diastereoisomers 24 and/or 25. The selectivity of this process is governed primarily by steric factors, such as the torsional and nonbonding interactions between substituents in the vicinity of the newly forming bond, and is called torquoselectivity. clockwise

R

H

//

H

R'

25

126

Name Reactions for Carbocyclic Ring Formations

Denmark and co-workers reported a good example of torquoselection in the silicon-directed Nazarov cyclization (see Section 3.4.5.1). They demonstrated that cyclohexenyl-derived divinyl ketones 26 cyclize to give the relative stereoisomer 27 as the major product (see Section 3.4.5.1 for the mechanism of the silicon-directed reaction).18'19 The use of bulky alkyl groups (such as i-butyl) and/or bulky silicon substituents gave the best selectivity, at the expense of the chemical yield. It is interesting that the corresponding cyclopentenyl-derived systems gave only poor torqueselectivity. H

FeCI,

SiRa

CH2CI2 0°C 63%

'Bu

H

28

94

3.4.4 Synthetic Utility 3.4.4.1

Simple Systems

The preparation of simple cyclopentenones can be achieved in modest to good yield using the Nazarov cyclization.4 Although many substitution patterns can be tolerated, in some cases regioisomeric double-bond isomers may be obtained. When relatively forcing conditions are used (strong acid, heat), the thermodynamically most stable regioisomer is usually produced. Acyclic, monocyclic and bicyclic precursors can all be employed, although the Nazarov cyclization is most frequently used as a cyclopentenone annulation method. In certain cases it is possible to control the torquoselectivity of the reaction. For example, substrate 29 is reported to give cyclopentenone 30 as the sole diastereoisomer in good yield.20 Me0 2 C Me0 2 C

29

30

Ph

Under sufficiently vigorous conditions aryl vinyl ketones also undergo the cyclization, producing annulated aromatic rings. For example, in 1953 Braude and Forbes reported the cyclization of 31, principally en route

Chapter 3 Five-Membered Carbocycles

127

to azulenes.21 Heating substrate 31 in a mixture of phosphoric and formic acid produced 32 in good yield (80%). O

H3PO4 ►

HC0 2 H 90

31

°C

The Nazarov cyclization was the key step in a synthesis of (±)trichodiene (35) by Harding and co-workers.22 One significant challenge in the preparation of this natural product is the presence of two adjacent quaternary stereocenters, and Harding and co-workers selected the Nazarov cyclization to tackle this problem. Although the reaction was not efficient under protic acid catalysis, the presence of an excess of boron trifluoride etherate enabled the production of 34a/b in good yield, whereby double bond migration had occurred. These specific reaction conditions were key to the success of this transformation, since under milder conditions or shorter reaction times, the expected α,β-unsaturated ketone was observed. 0

BF3.OEt2 (10equiv)

~AH ~f~ y iT\^-' +

CHCI3, reflux 33

89%

= ί~Λ

/

34a

0

~€

-

H JT H

»>-

'

Aί^Ϋ* J

35: (±)-trichodiene

~/ί i X -^34b

34a : 34b, 2.4 : 1

3.4.4.2

(^Substituted Substrates

As a general rule of thumb, α-substitution improves the cyclization efficiency of divinyl ketones. One explanation for this fact is the increased population of the s-trans/s-trans conformer 36a with a-substitution, which is predisposed toward cyclization.6 The α-substituents experience unfavourable non-bonded interactions in the s-cis conformation and, therefore, favour the s-trans conformer, whereas substrates containing α-hydrogen favour the s-cis conformation.

Name Reactions for Carbocyclic Ring Formations

128

s-trans/s-trans O

O

s-cis/s-trans

Ri 36a

I"

36b

O

s-cisls-cis

R1

R2

36c

As stated previously (see Section 3.4.3) the cationic reaction pathway of the Nazarov reaction allows for predictable stereoelectronic effects on differential substrate substitution. A theory on the stereoelectronic influence of a- and ß-substituents on substrate reactivity was developed by Denmark and co-workers, and stated that electron-donating substituents (cationstabilizing) in the α-position lower the activation barrier for cyclization by stabilizing the product oxyallyl cation (19, see Section 3.4.3) as opposed to the pentadienyl cation (18, see Section 3.4.3).23 Electron-donating substituents in the a-position, therefore, facilitate reaction. Coordinating functionalities in the α-position can also aid reactivity by enabling conformation control when the cyclization is mediated by chelating Lewis acids. Coordination of the Lewis acid to both the lone pair of the carbonyl oxygen and the functionality in the oc-position enforces the reactive s-trans conformation (see 36a), facilitating cyclization.6 The most widely used electron-donating oc-substituents are alkoxy groups. Indeed, these substrates are so reactive that they enabled the first truly catalytic examples of Lewis acid-catalyzed Nazarov reactions. Whereas stoichiometric quantities of Lewis acid are often required due to slow protonation of the Lewis acid enolate, a-alkoxy appended systems show efficient catalytic turnover.6 For example, Trauner and co-workers reported the efficient Nazarov cyclization of 37 in the presence of 10 mol % of aluminium trichloride.24 Not only do a-alkoxy groups lower the activation barrier to cyclization, but they also localize the resultant positive charge at one α-carbon, ensuring a highly regioselective elimination. AICI3(10mol%) CH2CI2, rt 37

88%

There are many examples of catalytic Nazarov cyclizations using Lewis acid catalysts in combination with a-alkoxy substituents. Tius and co-

Chapter 3 Five-Membered Carbocycles

129

workers reported one particularly interesting example using palladium catalysts.25

EtO.

Me

Pd (cat)

Me |-Pd(ll) R

EtO

40

39

O

EtO^V —' 42

R

Pd(OAc)2 20mOl%)

(

Θ

?(/Pd(ll) PdCI2(MeCN)2

EtO=^N>Me

DMSO, 0 2 80 °C

R 41

(2 mol%)

?H O^vA^Me

wet acetone rt

V, 43

While the product of this reaction somewhat resembles a Nazarov cyclization, it is thought that the reaction proceeds via a different mechanistic pathway and depends on the nature of the palladium catalyst. Activation of the olefin by palladium, followed by cyclization gives palladium enolate 41. When Pd(OAc)2 is used as the catalyst, ß-hydride elimination of 41 produces cyclopentenone 42, and molecular oxygen reoxidizes the palladium. On the other hand, when PdCl2(MeCN)2 is used as a catalyst, hydrolysis generates HC1 which results in rapid protonation of 41, giving cyclopentenone 43 as the product. Several examples of the efficient cyclization of substrates bearing electron-withdrawing groups in the α-position have been report. Indeed, despite the hypothesis that such substituents should retard the rate of Nazarov cyclization,2 several high-yielding procedures have been reported, and divinyl ketones bearing oc-ester and amide groups have proved effective in asymmetric Nazarov reactions (see Section 3.4.4.4).2 One important stereochemical consequence of a-electron-withdrawing groups is their predisposition to form /raws-stereoisomers. This is a consequence of facile equilibration of the α-stereocenter under the reaction conditions, giving the thermodynamically favoured trans product. Flynn and co-workers reported an efficient Nazarov cyclization of ßketoesters, such as 44.27 Under Bransted acid promotion, a range of substrates gave the irarcs-cyclopentanones after highly regioselective elimination, such as 45. Although they used predominately Z-configured substrates, it is important to note that EIZ isomerization occurs gradually over

Name Reactions for Carbocyclic Ring Formations

130

time. This can obviously give difficulties in correlating the stereochemical purity of the reagents with that of the products. In this case, it is possible that the predominance of Z increases reaction efficiency. O

O

Me

MeS03H

OEt

o^-L

"Pr

Me 44

O

88%Ό

A A oa

Me M

0

/

\

p r

45

To fully polarize the substrate, Frontier and co-workers have studied substrates bearing both a-electron-donating and a-electron-withdrawing substituents.28 Compounds such as 46 underwent the cyclization in very high yield, using just 2 mol % of a copper catalyst. Highly regioselective elimination was observed due to the electron-donating substituent, and the trans-product was isolated due to the electron-withdrawing substituent. The conclusions of this study regarding oc-substituents determined that ocelectron-donating substituents increase the reaction rate, whereas the effect of a-electron-withdrawing substituent is complex, possibly affecting the geometry of the substrate, the ability of the catalyst to bind to the substrate, and the facility of catalytic turnover. 0

Γ°ίΛΛ ^ ^

°

οΜβ

R

46

3.4.4.3

Cu(OTf)2 (2 mol%) CH2CI2, rt 99%

ß-Substituted Substrates

In general, substitution in the ß-position slows the reaction rate of the Nazarov cyclization;23 however, the nature and geometry of the substituents, with the corresponding steric and stereoelectronic implications has varying effects on the reactivity. For example, substrates with internal ß-substitution suffer steric hindrance when the cation adopts the necessary conformation for electrocyclization (see 48) and thus exhibit poor reactivity.6 From a stereoelectronic standpoint, electron-donating substituents (cationstabilizing) in the ß-position raise the activation barrier for cyclization by stabilizing the pentadienyl cation (18, see Section 3.4.3) relative to the oxyallyl cation (19, see Section 3.4.3).23 Therefore the size, nature, and geometry of the substituent is key to the reactivity profile of the substrate.

Chapter 3 Five-Membered Carbocycles

131

One of the most important ß-substituents in terms of controlling reactivity and selectivity is a trialkylsilyl group, and such systems will be discussed in Section 3.4.5.1. O

,LAorH

ΨIR

48

steric hindrance

Since steric hindrance disfavours cyclization for substrates with internal ß-substitution, double-bond isomerization is often a competing pathway. Indeed, West found that reductive Nazarov cyclizations (see Section 3.4.5.2) of either trans- or cw-disubstituted enones 49a or 49b, both produced a single diastereomeric product 50a.29 The stereochemistry of 50a corresponds to a conrotatory cyclization of trans-isomer 49a, thereby indicating that while the trans-isomer 49a cyclizes, the c/s-isomer 49b first isomerizes before cyclization. Recent studies by Frontier and co-workers on polarized Nazarov cyclizations also found that in the case of alkylidene ßketoester substrates (for example, see 46), reaction rates depended on the competing rate of isomerization, which depended on the nature of the ßsubstituent.28 n

BF3.OEt3 (1.1 equiv.)

Me.. JK. „.y Ph

'v.. Me 49a

Et SH ,ΛΓ, Λ3 . , (10 equiv.)

Ph

Me 50b

As opposed to these ß-sp -hybridized systems, allenyl and cumulenyl substrates (ß-sp-hybridized) exhibit excellent reactivity in the Nazarov cyclization.6 This enhanced reactivity is thought to derive from two factors: Minimization of steric interactions at the ß-position (increasing the

132

Name Reactions for Carbocyclic Ring Formations

population of the reactive s-trans conformer), and relief of allenyl strain in the transition state upon forming the allyl cation. As an example of their facile cyclization, Hashmi and co-workers reported that exposure of ketone 52 to silica gel resulted in conjugated dienone 54, presumably via the allenyl ketone 53.30

Dess-Martin periodinane

SiO,

Vi Et

53

54

Et3N 'BuO

R

CF 3 CH 2 OH reflux

55

f

BuO

58

59

0 I

CH2CF3 7-12%

42-69% 23

As predicted by stereoelectronic arguments, electron-donating substituents in the ß-position raise the activation barrier for cyclization by stabilizing the pentadienyl cation (18, see Section 3.4.3). In 2002, Harmata and Lee reported that ß-alkoxy substituents not only stabilize the pentadienyl cation but also promote a retro-Nazarov cyclization processes.31 Exposure of

Chapter 3 Five-Membered Carbocycles

133

ketone 55 to triethylamine in trifluoroethanol results in transient formation of an oxyallyl cation 57, which undergoes retro-electrocyclization to primarily form divinyl ketone 58 (with a small amount of a corresponding conjugate addition product 59). Efficient retro-cyclization required the presence of an additional pentadienyl cation-stabilizing group such as aryl or alkenyl. Examples do exist however, of productive Nazarov cyclizations bearing electron-rich heteroatoms in the ß-position. For example, cyclization of substrate 60 (albeit with the nitrogen atom contained within an aromatic indole moiety) was reported by Cheng and co-workers in 1996. Exposure of 60 to HC1 in refluxing dioxane resulted in the formation of product 61 in moderate yield. This key intermediate was then transformed into invertoyuehchukene (62), a dimer of 2-didehydroprenylindole.

62: Inverto-yuehchukene

3.4.4.4

Asymmetric Reaction

As with many asymmetric processes, there are three ways to control absolute stereochemistry in the Nazarov cyclization: Asymmetry transfer, the use of chiral auxiliaries, or asymmetric catalysis.5'6 It is important to realize, however, that there are two distinct processes operating that determine the stereochemistry of the product. To control the absolute stereochemistry of the ß-carbon atom(s), it is necessary to control the sense of conrotation, clockwise or counterclockwise (torquoselectivity, see Section 3.4.3). To control the absolute stereochemistry of the cc-carbon atom however, it is necessary to control the facial selectivity for enol protonation. In terms of asymmetry transfer, several effective means of controlling the absolute asymmetry of the product have emerged. Denmark and coworkers have published extensively on the use of silicon substituents to aid selectivity in Nazarov cyclizations (see Section 3.4.5.1). In one example of asymmetry transfer, they used a stereogenic trimethylsilyl-bearing carbon atom to control the sense of conrotation.3 Treatment of ketone 63 with ferric chloride gave product 64 in excellent yield and with complete transfer of asymmetry (see Section 3.4.5.1 for the mechanism of the silicon-directed

134

Name Reactions for Carbocyclic Ring Formations

reaction). The excellent transfer of asymmetry is due to clockwise conrotation maximizing overlap of the C-Si bond with the allylic carbocation all along the reaction coordinate. While the stereochemistry of the ß-carbon atoms of 64 is a result of the sense of conrotation, the stereochemistry at the α-carbon atom is thermodynamically favoured and set during proton transfer. FeCI3 CH2CI2

TMSO

-50 °C 63 86% ee

Elegant work by Tius and co-workers has demonstrated that the transfer of asymmetry need not be from an sp3 hybridized carbon atom. Instead, they have reported examples of the controlled Nazarov cyclization of allenyl vinyl ketones.5 In one such example, in situ formation of 67 resulted in efficient formation of cyclopentenone 68 with > 95% chirality transfer.34 The excellent axial to point chirality transfer is a result of the large tert-butyl substituent forcing counterclockwise rotation (as viewed by the reader).

Η . ^ ^ Ό '

"OMe

OTBS

65 98% ee

1.THF,-78°C 2. aq. KH2P04

w

-OMe Me

TBSO

^l·

67

''—OTBS 68 64%, 95% ee

Several groups have reported the use of chiral auxiliaries to control the stereochemical course of the Nazarov cyclization.5 In general, this strategy has proved effective, with the products isolated in good

Chapter 3 Five-Membered Carbocycles

135

diastereomeric excess. In one such example, Flynn and co-workers examined the cyclization of 70, prepared via a palladium-catalyzed hydrostannylation of 69, followed by acylation.27 Brensted acid-mediated cyclization gave the product cyclopentenone 71 in excellent diastereomeric excess and good yield. It is interesting that the kinetically favoured eis relative stereochemistry was obtained in this case. 1. Bu3SnH Pd(0), THF 2. tigloyl chloride CuCI

Ph

70

MeS03H, CH2CI2 -78 to 0 °C

ΥΛΛ P

/

Ph

c Ph

O

71

Perhaps the most elegant and attractive method to control absolute stereochemistry, however, is the use of asymmetric catalysis, and several examples of this approach have been applied to the Nazarov cyclization. Trauner and co-workers were the first to report a single example of a successful asymmetric Nazarov cyclization catalyzed by chiral scandium complex in 2003.24 In the exact same issue of the journal however, Aggarwal and co-workers reported a more in-depth study using copper pyBOX complexes.26 Inspired by Evans's work on copper bisoxazoline complexes in asymmetric synthesis, Aggarwal and co-workers hypothesized that these type of complexes offered potential to control the direction of conrotation. Indeed, using stoichiometric amounts of the complex formed from CuBr2, AgSbFö (which abstracts the halide anions) and 74, a variety of substrates 72 underwent the cyclization giving the products 73 in up to 88% ee, with the thermodynamically favoured irarcs-configuration after proton transfer. Lowering the loading of the complex resulted in lower yields (but not enantioselectivities), and in general a phenyl group in the ß-position was required for acceptable reaction rates. Aggarwal and co-workers proposed a stereochemical model for their reactions, whereby in the case of the CupyBOX complexes, the proposed intermediate 75 adopts a square-based

136

Name Reactions for Carbocyclic Ring Formations

pyramid geometry and the alkene substituents are pushed away from the isopropyl groups of the ligand. This places the bonding lobes of the two corresponding orbitals in close proximity, making them predisposed to cyclization in a clockwise manor. R1

0

0 OEt

Ligand 74 ►

CuBr2, AgSbF6 CH2CI2, rt

Ph' 72

In 2004, Trauner and co-workers published a follow-up communication on their asymmetric catalytic system.35 Under optimized conditions, they were able to achieve good to excellent levels of enantioselectivity for a variety of substrates using complex 78 with lower catalyst loadings (10 mol %). It is important to note however, that the specific use of an alkoxy dienone substrate lacking a ß-substituent on one of the alkenes (such as 76) was required for high yields and good enantioselectivities. Since the stereocenter formed during electrocyclization is subsequent destroyed on deprotonation of the allylic cation (see Section 3.4.3), the control of absolute stereochemistry in this case is solely due to facially selective reprotonation of the enolate.

,0.

R

10 mol % 78 MeCN, ►

76

3 A mol. sieves, rt

"R 77 ee: 72-97%

Chapter 3 Five-Membered Carbocycles

137

Rueping and co-workers have reported one of the most impressive examples of a Nazarov cyclization under asymmetric catalysis. They have shown that chiral Bronsted-acid catalysis outperforms the chiral Lewis acid catalysts used to date and have demonstrated the efficient cyclization of a variety of substrates 79 with moderate to excellent diastereoselectivity and good to excellent enantioselectivity.36 Only low catalyst loadings (2 mol %) are required of chiral acid 81 to catalyze the reaction efficiently. Interestingly, the reaction primarily generates the cw-cyclopentanones 80a, as opposed to the Lewis acid-catalyzed reactions that provide the transproduct (see 73).

79

R1

2 mol % 81

R2

CHCI3 0°C

Ar

fTV^i >

80a (major)

^Ar

H

<' I

so 2 CF 3

81: Ar = 9-phenanthryl 80b (minor) Yield: 45-91% cis/trans: 1.5:1 to 1:0 ee: 86-98%

3.4.5 Variations and Improvements 3.4.5.1

Silicon-Directed Nazarov Cyclization

Denmark and co-workers have published extensively on the use of ß-silyl substituted divinyl ketones (see 82) in the Nazarov cyclization.4 Such silyl groups control the collapse of the intermediate cyclopentenylic cations 84, and thus aid the regioselectivity of elimination, as well as the minimization of side reactions (secondary cationic rearrangements). Such stabilization derives from the known ß-cation stabilizing effect of silicon, which through stabilization of 84, ensures maximum efficiency of the cyclization, with controlled formation of the final double bond. An important consequence of the final elimination step is that the double bond is placed in the thermodynamically less stable position (see 85). The most common Lewis acid used in the silicon-directed Nazarov cyclization is anhydrous iron(III) chloride, at temperatures below ambient.4 Alternatively, in cases where the

138

Name Reactions for Carbocyclic Ring Formations

substrate is slow to react, or sensitive to the oxidizing properties of iron(III) chloride, boron trifluoride etherate or zirconium tetrachloride are often employed. R

R2

OFel_n

Fed,

1

SiMe-,

82

ΟΗ2Ι-Ί2

©ll

R2'

83

SiMe3

T

OFeL,

CISiMe3 + H+ 85

"-

84

SiMe·,

One particularly elegant use of the silicon-directed Nazarov cyclization was in the synthesis of the angular inquinane silphinene (89), by Miesch and co-workers. Addition of a large excess of boron trifluoride etherate in refluxing ethylbenzene to 86 ensured annulation of the required third ring. Notably, the benzyloxy group was also eliminated under the reaction conditions, and the product 88 was subsequently converted into the natural product 89. SiMe3 OBn BF3-OEt2 (4 equiv) EtPh reflux 50%

SiMe3 OBn

88

Chapter 3 Five-Membered Carbocycles

139

Although the majority of work in this area has used silicon-based directing groups, it is important to note that similar control mechanisms are in operation in ß-stannyl appended substrates. Such functionality was harnessed in the synthesis of prostaglandin analogues (see 91) by Johnson and co-workers.38 The use of the tributyl stannyl group in substrate 90 ensured the kinetic product was formed, whereby the double bond is located in the least substituted position. BFvOEto Sn"Bu3 CH2CI2 OBn

90

20 °C

Placement of the directing group need not be at the ß-carbon atom destined to become part of the cyclopentenone ring. Indeed, often substrates containing allyl silanes (silyl groups in the a' position) react at increased rates compared to their ß-substituted counterparts.4 Once again, the positioning of the silyl group determines the regioselectivity of elimination. For example, Kang and co-workers demonstrated that exposure of trimethylsilyl derivatives such as 92 (S1R3 = SiMe3) to iron(III) chloride results in the formation of the exocyclic double bond (see also 63-64). 39 On the other hand, Pulido and co-workers exploited the diminished tendency of bulkier silyl groups to undergo protodesilylation and thus isolated product 94 upon treatment of 92 (SiR3 = Si'BuPh2) with TFA.40

1

R

R2

FeCU

SiR-,

SiR3 = SiMe3 R2 93

TFA, THF, 60 °C

R1

SiR3 = SifBuPh2

R2

92

SiR, 94

It is important to note that silyl-appended substrates have also demonstrated applicability in the control of torquoselectivity (see Section 3.4.3), and asymmetric transfer (see Section 3.4.4.4) in the Nazarov cyclization. 3.4.5.2

"Interrupted" Nazarov Cyclizations

Following electrocyclic ring closure, the resulting cyclopentenylic cation (for example 11, see 3.4.3) is stable enough to be intercepted in other reaction

Name Reactions for Carbocyclic Ring Formations

140

pathways. West and co-workers have most extensively explored this reaction manifold and have termed the processes "interrupted" Nazarov cyclization pathways.41 A variety of examples have emerged such as formal cycloadditions, cationic cascades, and reductive trapping.6

BR.OEto

Me

Me

Θ

F3BV s

Me

O

H

Me

H20 Me

97

H

HC

Me 98

Me

V Me/~Me H 99

For example, West and co-workers have demonstrated the efficient intramolecular capture of the cyclopentenylic cation by pendent alkenes.41 Exposure of substrate 95 to boron trifluoride etherate results in electrocyclic ring closure to give 96 under the expected Nazarov pathway, followed by intramolecular trapping by first the alkene and then the enolate oxygen (formal [3 + 2] cycloaddition). Hydration of the enol ether upon workup gives products such as 99 in high stereoselectivity, containing five new stereocenters. This particular pathway is sensitive to substrate structure, whereby the carbon tether between the alkene and dienone must be two carbon atoms long, and there must be substitution in both cc-positions. Switching to a terminal alkene results in several alternative pathways, including hydride shifts, chloride anion capture, and proton elimination.42 Other formal cycloadditions have been demonstrated using alternative tethers.6 Capture of the cationic intermediates formed in "interrupted" Nazarov pathways by aromatic groups is equally possible.6 One particularly impressive example was also reported by West and co-workers. 3 Exposure of substrate 100 to titanium tetrachloride at low temperature resulted in the formation of pentacyclic product 103 in complete diastereoselectivity and excellent yield (98%). This process involves initial electrocyclization to give

141

Chapter 3 Five-Membered Carbocycles

intermediate 101, followed by 6-endo trapping with the pendent olefin and subsequent capture by the phenyl group. During optimization, several intermediate products were observed that could be directly traced back to reactive intermediates 101 and 102.

TiCI4

-78 °C 5 min

100

101

HoO

103

102

Intermolecular capture of cationic intermediates resulting from Nazarov cyclizations has been demonstrated with added nucleophiles.6 For example, allyl silanes can be used to either generate oc-allyl ketones or [3 + 2] cyclization products.44 Θ

O BF3.OEt2

R 104

or SnCI4 (0.1 equiv) CH2CI2

-78 °C

R^J^R R

R 105

"

O

HSiEt3 R ^ y . R

(2eqUiC)

OSiEt3

R^A^R

/ Λ ' f^\ 106

107

One important development however, was the identification of a reductive trapping pathway, allowing the isolation of saturated cyclopentanones. Lewis acid promoted Nazarov cyclization of substrate 104, followed by reductive quenching by triethyl silane resulted in the formation of ketones 106 and enol silanes 107. Such a reaction process requires only 10 mol % of the Lewis acid promoter, with hydride addition occurring at the less-substituted position of the oxyallyl cation 105. Mixtures of compounds isomerie at the a-positions were isolated in these reactions due to the rapid epimerization of these centers during acidic workup.

Name Reactions for Carbocyclic Ring Formations

142

3.4.5.3

Related Reactions

It has long been recognized that the construction of cyclopentenones via the Nazarov cyclization can be achieved by using functional equivalents of divinyl ketones or other reaction intermediates. The review published by Denmark and co-workers contains many early examples.4 For example, exposure of ge/w-dichlorocyclopropylmethanol 108 to acid results in the solvolytic generation of intermediate 109, followed by a Nazarov-type cyclization and hydrolysis to yield cyclopentenone HO.45 Formation of intermediate 109 presumably occurs through cyclopropylcarbinyl cation rearrangement, followed by loss of a proton to give a divinyl dichloride. Ionization of the divinyl dichloride would give intermediate 109. CL

CI

Me. Μ β

Γ

CI

47% HBr

^ Ο Η

Me

^

100 °C

Me

109

108

110

Rautenstrauch reported another mechanistically intriguing example.46 Treatment of enynol acetate 111 with a palladium(II) catalyst in warm acetonitrile resulted in the formation of cyclopentenone 115. The proposed mechanism involves generation of divinyl cationic species 113, followed by electrocyclization, and elimination of the palladium(II) electrofuge in a manner comparable to the silicon-directed Nazarov cyclization (see Section 3.4.5.1). PdCI2(MeCN)2 *HOAc, MeCN 60 °C

ft

OAc

Me v - . 0

[Pd]

113

112

OAc

1 114

115

Intermolecular trapping of Nazarov intermediates with oxygen functionalities has been reported by several groups (interrupted Nazarov

Chapter 3 Five-Membered Carbocycles

143

pathway, see Section 3.4.5.2). In one report, De Lera and co-workers described the efficient generation of product 119 from acetal 116.47 Mechanistically, the reaction most likely proceeds via acid mediated acetal opening to give 117 (pentadienyl cation derived from a conjugated aldehyde equivalent rather than a divinyl ketone), followed by electrocyclization and oxygen trapping to give 119.

117

Bu

V >

Me

®

—OH 118

119

An imaginative approach to the cephalotaxine alkaloids was reported by Li and co-workers and used a functional equivalent of the Nazarov cyclization.48 Iron-mediated oxidation of substrate 120 gave intermediate 121. Tautomerization of 121 to 122 followed by electrocyclization gave annulated product 123. This key intermediate was subsequently converted into cephalotaxine (124). FeS0 4 air AcOH

144

Name Reactions for Carbocyclic Ring Formations

3.4.6 Experimental 3.4.6.1

Standard Bronsted acid-mediated conditions O

125

PPA 100 °C 62%

mV cis-Tricyclo[6.3.0.(T']undec-l(8)-en-2-one ( 126)

49

1 ,Γ-Dicyclo-pentenyl ketone (19 g) was added with good stirring to hot (100 °C) polyphosphoric acid (100 g) under nitrogen. The colorless PPA immediately turned dark brown. The reaction mixture was stirred for 30 min at 100 °C. After this time, the oil bath was replaced with an ice bath, and ice (100 g) was added immediately to the hot acid. The mixture was stirred for 5 min. A dark precipitate formed during the addition of ice but dissolved on addition of ether. Standard workup (ether) gave a brown oil (19 g), which was distilled carefully to give the tricyclic enone 126, better than 95% isomerically pure by GLC on OV-225, as a colorless oil (11.9 g, 62%): bp 60-63 °C (0.05 mm Hg). 3.4.6.2

Lewis acid-catalyzed conditions O

AIC(3(10mol%) CH2CI2, rt

37

88%

βρ 38

Chapter 3 Five-Membered Carbocycles

145

2,3,3a,5,6,8a-Hexahydro-l^,4^-7-oxa-cyclopenta[a]inden-8-one (38)24 To 0.011 g (0.079 mmol) A1C13 in CH2C12 (2 mL) was added 0.140 g (0.788 mmol) 37 in CH2CI2 (2 mL). The reaction mixture was stirred for 40 min before it was quenched with water (4 mL). The mixture was further diluted with CH2CI2 (10 mL). The two layers were separated and the aqueous layer was extracted with CH2CI2 ( 2 x 5 mL). The combined organic layers were washed with brine (10 mL), dried, filtered and concentrated in vacuo. The product was purified by column chromatography (EtOAc:hexanes = 1:4) to afford 0.124 g (88%) 38 as colorless oil. R/0.19 (EtOAc:hexanes = 1:4). 3.4.6.3

Silicon-directed Nazarov conditions FeCI3 SiMe

127

3

H

O

CH 2 CI 2 - 7 5 4?

W

'H

128

c«,ira«5-l,3,4,5,6,7,8 ? 8a-Octahydroazulen-l-one (128)18 Anhydrous iron trichloride (345 mg, 2.13 mmol) was added in one portion to a cold (-5 °C) solution of (£)-l-(l-cycloheptenyl)-3-trimethylsilyl-2-propen1-one (450 mg, 2.02 mmol) in CH2CI2 (25 mL). The mixture was stirred at -5 °C for 50 min by which time the starting material had been consumed. Water (20 mL) was added, the mixture was diluted with CH2CI2 (10 mL), and the organic layer was removed. The aqueous phase was extracted with CH2CI2 (2 x 30 mL), and the individual organic extracts were washed with saturated aqueous ammonium chloride solution and brine. The combined organic extracts were dried (K2CO3) and concentrated. The residue was purified by flash chromatography on silica gel (EtOAc:hexanes = 1:4) followed by distillation, bp 110 °C (0.01 torr) to afford azelenone 128 (225 mg, 74%). GC analysis revealed the product to be an 85/15 mixture of tisana trans-isomers. 3.4.7 1. 2. 3. 4. 5. 6. 7.

References

[R] Santelli-Rouvier, C; Santelli, M. Synthesis 1983,429^142. [R] Denmark, S. E. In Comprehensive Organic Synthesis; Trost, B. M., Fleming, I., Eds.; Pergamon Press: Oxford, 1991; Vol. 5, pp 751-784. [R] Krohn, K. Org. Synth. Highlights 1991, 137-144. [R] Habermas, K. L.; Denmark, S. E.; Jones, T. K. Org. React. 1994, 45, 1-158. [R] Tius, M. A. Eur. J. Org. Chem. 2005, 2193-2206. [R] Frontier, A. J.; Collison, C. Tetrahedron 2005, 61, 7577-7606. Vorländer, D.; Schroeter, G. Chem. Ber. 1903, 36, 1490-1497.

146 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18. 19. 20. 21. 22. 23. 24. 25. 26. 27. 28. 29. 30. 31. 32. 33. 34. 35. 36. 37. 38. 39. 40. 41. 42. 43. 44. 45. 46. 47. 48. 49.

Name Reactions for Carbocyclic Ring Formations Francis, F.; Wilson, F. G. J. Chem. Soc. 1913, 2238-2247. Blomquist, A. T.; Marvel, C. S. /. Am. Chem. Soc. 1933, 55, 1655-1662. Mitchell, D. T.; Marvel, C. S. J. Am. Chem. Soc. 1933, 55, 4276-^279. Nazarov, I. N.; Zaretskaya, 1.1. Bull. Acad. Sci. U.R.S.S., Classe sci. chim. 1942, 200-209. Nazarov, I. N.; Zaretskaya, 1.1. Zh. Obshch. Khim. 1957, 27, 693-713. Nazarov, I. N.; Zaretskaya, 1.1. Zh. Obshch. Khim. 1960, 30, 746-754. Braude, E. A.; Coles, J. A. J. Chem. Soc. 1952, 1430-1433. Sorenson, T. S. J. Am. Chem. Soc. 1967, 89, 3782-3794. Motoyoshiya, J.; Yazaki, T.; Hayashi, S. J. Org. Chem. 1991, 56, 735-740. Woodward, R. B. Chem. Soc. Special Publication No. 21, 1967, 217-249. Jones, T. K.; Denmark, S. E. Helv. Chim. Ada 1983, 66, 2377-2396. Denmark, S. E.; Habermas, K. L.; Hite, G. A.; Jones, T. K. Tetrahedron 1986,42, 2821-2829. Wada, E.; Funiuara, I.; Kanemasa, S.; Tsuge, O. Bull. Chem. Soc. Jpn. 1987, 60, 325-334. Braude, E. A.; Forbes, W. F. J. Chem. Soc. 1953, 2208-2216. Harding, K. E.; Clement, K. S.; Tseng, C. Y. J. Org. Chem. 1990, 55,4403^410. Denmark, S. E.; Habermas, K. L.; Hite, G. A. Helv. Chim. Acta 1988, 71, 168-194. Liang, G.; Gradi, S. N.; Trauner, D. Org. Lett. 2003, 5,4931^4934. Bee, C; Ledere, E.; Tius, M. A. Org. Lett. 2003, 5,4927^930. Aggarwal, V. K.; Belfield, A. J. Org. Lett. 2003, 5, 5075-5078. Kerr, D. J.; Metje, C; Flynn, B. L. Chem. Commun. 2003, 1380-1381. He, W.; Herrick, I. R.; Atesin, T. A.; Caruana, P. A.; Kellenberger, C. A.; Frontier, A. J. J. Am. Chem. Soc. 2008, 130, 1003-1011. Giese, S.; West F. G. Tetrahedron 2000, 56, 10221-10228. Hashmi, A. S. K.; Bats, J. W.; Choi, J.-H.; Schwarz, L. Tetrahedron Lett. 1998, 39, 7491-7494. Harmata, M.; Lee, D. K.J. Am. Chem. Soc. 2002,124, 14328-14329. Cheng, K.-F.; Cheung, M.-K. J. Chem. Soc, Perkin Trans. 1 1996, 1213-1218. Denmark, S. E.; Wallace, M. A.; Walker, Jr., C. B. J. Org. Chem. 1990, 55, 5543-5545. Hu, H.; Smith, D.; Cramer, R. E.; Tius, M. A. J. Am. Chem. Soc. 1999,121, 9895-9896. Liang, G. Trauner, D. J. Am. Chem. Soc. 2004,126, 9544-9545. Rueping, M.; leawsuwan, W.; Antonchick, A. P.; Nachtshein, B. J. Angew. Chem., Int. Ed. 2007, 46,2097-2100. Miesch, M.; Miesch-Gross, L.; Franck-Neumann, M. Tetrahedron 1997, 53, 2103-2110. Peel, M. R.; Johnson, C. R. Tetrahedron Lett. 1986,27, 5947-5950. Kang, K.-T.; Kim, S. S.; Lee, J. C; U, J. S. Tetrahedron Lett. 1992, 33, 3495-3498. Barbero, A.; Castreno, P.; Garcia, C; Pulido, F. J. J. Org. Chem. 2001, 66, 7723-7728. Bender, J. A.; Blize, A. E.; Browder, C. C; Giese, S.; West, F. G. J. Org. Chem. 1998, 63, 24302431. Browder, C. C; West, F. G. Synlett 1999, 1363-1366. Wang, Y.; Arif, A. M.; West, F. G. J. Am. Chem. Soc. 1999,121, 876-877. Giese, S.; Kastrup, L.; Stiens, D.; West, F. G. Angew. Chem., Int. Ed. 2000, 39, 1970-1973. Hiyama, T.; Tsukanaka, M.; Nozaki, H. J. Am. Chem. Soc. 1974, 96, 3713-3714. Rautenstrauch, V. J. Org. Chem. 1984, 49, 950-952. de Lera, A. R.; Rey, J. G.; Hrovat, D.; Iglesias, B.; Lopez, S. Tetrahedron Lett. 1997, 38, 74257428. Li, W.-D. Z.; Wang, Y.-Q. Org. Lett. 2003, 5, 2931-2934. Eaton, P. E.; Giordano, C; Schloemer, G.; Vogel, U. J. Org. Chem. 1976, 41, 2238-2241.

Chapter 3 Five-Membered Carbocycles

3.5

147

P a u s o n - K h a n d Reaction

Louis S. Chupak 3.5.1

Description R Rs

Co2(CO)6 1

-R

». Rs 2

The Pauson-Khand Reaction (PKR) is a formal [2 + 2 + 1] cycloaddition of a cobalt-complexed alkyne 1, an alkene and carbon monoxide. Three bonds are formed in a single reaction to give a significant increase in structural complexity on going from starting materials to product. With unsymmetrical alkynes, the reaction tends to join the components together regioselectively to place the larger alkyne substituent next to the carbonyl group. Less regioselectivity is seen for the alkene component. The ability to predict regiochemistry, a rapid increase in synthetic complexity and the frequency of 5-membered rings in synthetic targets has made this reaction the focus of numerous mechanistic and synthetic studies as well as multiple reviews.1"12 3.5.2

Historical Perspective

In 1971 at the University of Strathclyde in Glasgow, Professor Peter Pauson reported on the retro-Diels-Alder reaction of norbornadiene 3 induced by dicobalthexacarbonyl complexes of acetylene or phenylacetylene 1 to provide dicarbonylcyclopentadienylcobalt complexes 4 in high yield.13 Almost as an after thought, he mentions "In addition to the above products, the reaction of norbornadiene with complexes 1 yields hydrocarbon and ketonic products derived from norbornadiene, acetylene and carbon monoxide." 1

R

(OC) 3 Co^

2

R

Co(CO)3

0(λ

Co

XO

Φ>

1

R

0

R2

H H 5

Name Reactions for Carbocyclic Ring Formations

148

Two years later, in the paper most often cited as the original PKR disclosure, Pauson identifies the "ketonic product" as a cyclpentenone, demonstrates that the larger alkyne substituent prefers to occupy the position adjacent to the carbonyl and that the endo-form 5 is the kinetic product when norbornadiene is the alkene.14 The PKR has tremendous synthetic potential because of the resulting increase in synthetic complexity and the frequency of five-membered rings in synthetic targets. This potential has made the PKR the focus of numerous reviews, mechanistic studies and synthetic strategies. Thus this chapter cannot attempt to provide a complete coverage of the PKR. Instead the aim is to provide readers with enough background to understand new developments and to decide if a PKR can be applied to their work. 3.5.3

Mechanism

(CO) 3 Co

^ψΟο(00)3

Γ^

HO'C

2

R

In 1985 both Magnus15 and Schore16 independently proposed identical mechanisms based on stereochemical and regiochemical preferences observed in the product. Magnus's hypothesis was based on the stereochemical results for an intramolecular cyclization. He proposed that the product arose from formation of a metallocycle intermediate 7 or 8, carbon monoxide insertion to give 9, acyl migration from cobalt to carbon and reductive elimination of cobalt to form 10. The relative thermodynamic stability of the metallocycles 7 and 8 controlled the final product ratio. In the

Chapter 3 Five-Membered Carbocycles

149

case of an allylic substituent R1 as in 6, the more stable isomer places the R1 group on the exo face of the newly formed bicyclic system as in 7, trans to the R2 group and eis to the adjacent hydrogen at the ring fusion. Thus the stereochemical outcome of the reaction is derived from intermediate 7 and not intermediate 8. Similarly, when a propargylic group R1 is present as in 11, the more stable isomer places the R1 group on the exo face of the newly formed bicyclic system as in 12, on the opposite face of the R2 group and on the same face as the hydrogen at the ring fusion. The steric clash between R1 and R2 in 13 is avoided in 12.

R1

(CO) 3 Co

\ H ^ C o ( C O ) 3 110-C

^H

R2

11

12

D .i R ec

,i CO

H

14

Schore's mechanistic proposal came from observing the preferred regiochemistry of the products derived from the intermolecular reaction of 8oxabicyclo[3.2.1]oct-6-ene derivitives 16 with alkynes. As in Pauson's norbornene examples, only the exo-products resulting from attack on the less-hindered face of the alkene were observed. Schore proposed that the product-determining step was insertion of the less-hindered face of the alkene into the less-hindered alkyne carbon-cobalt bond. Four possible modes of attack, two syn- and two and- on the exo-face of the alkene are possible. Two of these differ only in the location of the "spectator" cobalt atom and are not shown. In the preffered mode 16-anti, the alkyne group R1 is farthest from the newly forming cobalt-carbon bond. The reacting cobalt is anti to

Name Reactions for Carbocyclic Ring Formations

150

the bridgehead group R . In 16-syn, a steric clash occurs between the cobalt's carbon monoxide ligands and the allylic R1 group. Migratory insertion of CO into a metallocycle cobalt-carbon bond, acyl migration from cobalt to carbon, and reductive elimination follow to give the observed products 17. anti attack

Co

H

16-ant/

*■ O

R1

V

17

O

16-syn

\

I

R

'

CO

CO

R2

syn attack

The mechanism resulting from these original studies is shown below. The alkyne S is first coordinated by cobaltoctacarbonyl with loss of two equivalents of carbon monoxide to give a well characterized complex 1-1. Upon heating, loss of a third equivalent of carbon monoxide opens a coordination site to provide 1-2 and allows cobalt to complex the alkene as in 1-3. The alkene inserts into the least hindered cobalt-carbon bond to form the cobaltacycle 1-4. Carbon monoxide inserts into the new cobalt-carbon bond to give 1-5. Next, acyl migration from cobalt to carbon forms the final carbon-carbon bond as in 1-6. Finally, a formal reductive elimination of the "spectator" cobalt releases the product cyclopentenone P and cobalthexacarbonyl. The cobalt is then ready for another catalytic cycle. In practice the cobalt is most often used stoichiometrically. The alkyne cobalt complex is a stable species that can be purified and isolated by silica gel chromatography. Conditions for catalytic turnover of the cobalt have been reported. The original mechanistic proposal has remained largely unchanged and is supported by subsequent theoretical17'18 and experimental19 results. The key findings are (1) Initial loss of carbon monoxide is energetically disfavoured and requires heat, the presence of weak ligands, or activating agents to liberate a CO ligand. (2) The alkene-insertion step determines the regio- and stereochemistry of the final product. This step is also disfavoured energetically and explains the observed importance of reactive alkenes for

Chapter 3 Five-Membered Carbocycles

151

succesfull reactions. This step, 1-3 to 1-4, is considered to be rate determining. (3) Acyl migration, 1-5 to 1-6, is energetically favoured over other possible alternative pathways. (4) The "spectator" cobalt exerts electronic influences on the reacting metal center through the metal-metal bond. -RL

Rs

+ Co2(CO)8

-2 CO

-

//-

Rs

R

^vy*

L

<& Co2(CO)6

Rs

„

b

^ O U ,

3

^Co(CO)3 V -

Rs ^ - 2 CO

1-1

Co(CO)8

-co^

RLX ^Co(CO)3 R s^Co(CO)2 I-2

+ 2 CO/ R

s,

p

RL

Co(CO)6

I-3

R

Rs^c^-co R

RL\

K

Y^Co(CO)3

Rs

tL>i° I-6

R L

L\

\pCo(CO)3 s^Co-(CO)2

V;Co(CO)3 +L

R 1-4

An X-ray crystal structure of an alkene cobalt complex has been reported by McGlinchey.20 A mixture of 18a and 18b formed at room temperature and these products were separated by flash chromatography. Although heating did not induce the PKR to occur, 18a was proposed to be

152

Name Reactions for Carbocyclic Ring Formations

an arrested η -alkene-pentacarbonyldicobalt-alkyne complex in the PKR pathway (see intermediate 1-3 above). A comparison of the X-ray crystal structures showed the coordinated double bond in 18a to be slightly longer than the uncoordinated double bond of 18b, 1.403 A versus 1.336 À, respectively. The boat conformation of the seven-membered ring was also more pronounced in 18a as the cobalt pulled the double bond toward itself. The geometry of the alkyne was similar to that normally observed in hexacarbonyldicobalt-alkyne complexes with the propargylic centers "bent back" from 180° to approximately 143° as expected. Co 2 (CO) 8

THF, 65 °C

»-

»

/ Ί43°

(COhCoWk-^

(CO)3Co^

18b

As will be seen in the following sections, the mechanistic proposal has enabled researchers to improve upon the original reaction conditions and successfully apply the PKR to the synthesis of complex target molecules. In addition, a number of reports describe diverting the reaction to provide alternative products. The subject of alternative products that can arise intentionally and unintentionally is nicely reviewed by Krafft.21 3.5.4 Variations and Improvements Initially, the PKR was limited to reactive alkenes (such as norbornene), required high temperatures (60-110 °C), high CO pressures, and long reaction times. Alkenes were, in general, minimally substitutued or strained. Regioselectivity with nonsymmetric alkenes provided mixtures of regioisomer in contrast to the more predictable final disposition of alkyne substituents. Intramolecular reactions were superior to comparable intermolecular reactions. Early versions of the reaction were performed under an atmosphere of carbon monoxide and gave poor to modest yields. Since its discovery, numerous modifications have been designed to address the issues and expand the scope of the reaction. These modifications include the use of additives, adsorption onto solids before heating, addition of coordinating ligands, inclusion of temporary cleavable tethers, sonication, microwave irradiation, and solvent variation. Finally, great strides have been

Chapter 3 Five-Membered Carbocycles

153

made toward reactions using substoichiometric cobalt and controlling absolute stereochemistry. The PKR reaction has always been characterized by good functional group compatibility. Examples abound where amines, amides, sulfonamides, sulfides, alcohols, ketones, esters, and silyl ethers are contained in the reactants. In addition, because substituted alkenes react more slowly than unsubstitued alkenes selectivity can be achieved when multiple alkenes are contained in the reactants. An interesting example of functional group compatibility was demonstrated in which a metal carbene not only survived the PKR but accelerated it.22 For example, the tungsten carbene 19 formed the cyclopentenone 20 in 80% yield at 0 °C. // V

W(CO)5 11.

Co2(CO)8

Co,(CO)« 0 °C, 3 h

19

// V

W(CO)5 "

N

20

In an attempt to improve on the original PKR, Pauson reported on the effects of various additives. Phosphines, ether as preformed cobalt species or simply added to the PKR, only served to reduce the rate and yield of the reaction. On the other hand, ultrasound and tributylphosphine oxide proved equally effective at accelerating the rate of reaction and increasing the overall yield of the PKR. The reaction yields were described as erratic: varying irreproducibly as the reaction atmosphere was changed. The use trimethylamine-N-oxide was mentioned but no results were reported.

21 Reaction Conditions

% Yield (22a : 22b)

/-octane, 60 °C , 24 h (conventional PKR)

29 : 0

Si0 2 , 45 °C, 30 min., 0 2

75 : 0

Si0 2 , 45 °C, 30 min., Ar

15:40

Name Reactions for Carbocyclic Ring Formations

154

Smit described the rate-accelerating effect of preabsorbing the PKR reactants onto a solid support and removing the solvent before heating. Cyclopentenone 22a was formed in superior yields at reduced temperatures under these dry state absorption conditions.24'25 Various solid supports and conditions were examined. Both silica (S1O2) and alumina (AI2O3) worked equally well. The reaction rate was independent of pH. The optimal conditions required 10-20% water content and an oxygen atmosphere. Smit proposed that the rate acceleration was due to a hydrophobic effect that forced the reacting alkene and alkyne together to reduce the entropy barrier for cyclization. Interestingly, when the PKR was performed under an inert atmosphere the dominant product 22b arose from cleaving the allylic (or perhaps propargyllic) ether bond. In 1990, a major breakthrough for the utility of the PKR occurred when Schreiber reported the use of 7V-methylmorpholine-./V-oxide (NMO) as a promoter.26 As shown, the addition of NMO allowed the reaction to be run at ambient temperature and produced enhanced diastereoselectivity.

23

24a

Reaction Conditions

24b

% Yield

24a : 24b

NMO, CH2CI, room temperature

68

11:1

CH3CN, 82 °C

75

4:1

CH3CN, 45 °C, sonication

45

3:1

It was proposed that NMO oxidized one of the carbon monoxide ligands to carbon dioxide to open up a coordination site for the alkene. Alternatively (or additionally), NMO may act to scavange CO to make the dissociation of the CO ligand irreversible. Subsequent to this work, a 01

98 9Q

number of TV-oxides, including polymer-bound TV-oxides, ' have been shown to accelerate the PKR. More than one equivalent TV-oxide is usually required to observe the accelerating effects. Thus polymer-bound TV-oxide offers the advantage of simplifying the work-up. Trimethylamino-TV-oxide (TMANO) and NMO are the two most common TV-oxides used to accelerate the PKR.

Chapter 3 Five-Membered Carbocycles

155

Lewis bases30'31 also accelerate the PKR by supposedly acting as weak ligands to promote the dissociation of CO and to stabilize intermediates. However, density functional theory (DFT) calculations described by Gimbert demonstrate no acceleration for the loss of CO in the presence of a Lewis base. Instead, the calculations suggest that the Lewis base stabilizes the cobaltacycle 1-4. This stabilization effectively makes the olefin insertion irreversible. Dimethylsufoxide,33'34 amines35'36 such as cyclohexyamine,37 various sulfides,38 water,42 alcohols, thioureas,39"41 and ethers42 have all shown accelerating effects. Heterogenous additives such as molecular sieves ' 4 or preabsorbtion of the cobalt catalyst onto charcoal5 have also been employed to accelerate the PKR. As with other additives, the current view is that these additives promote the dissociation of, or trap, CO to provide the reactive catalyst or increase the concentration of the alkene coordinated intermediate 1-3. The improved yields observed with intramolecular versus intermolecular PKRs have encouraged attempts to facilitate the reaction with a cleavable tether. Ether46'47 and silyl groups have been employed as covalent tethers that can be cleaved after the PKR. Several authors have reported on the use of silicon tethers to promote the PKR.48-50 However, the success of the PKR varies considerably with the substituent pattern on the silicon, the alkene and the alkyne. Dobbs has explored the use of silyl ether, silyl acetal, and silyl alkyl tethers in the PKR.51 Under his conditions, only sily ethers produced cyclopentenones. The best results required two isopropyl groups on the silicon. The 6,5-ring system 26 (n = 1) was formed in 75% under the best conditions, The 7,5 ring system (n = 2) from the homopropargyl silyl ether failed to form under these conditions. This result illustrates one of the current limitations of the PKR. There are very few examples for the formation of medium-size ring systems.52-54 Co2(CO)8 NMO 25

/

-Si όI .

26(n = 1,75%;n = 2,0%)

The PKR can be performed in a wide variety of organic solvents. The reaction is compatible with ionic liquids,55'56 nonpolar solvents such as hexane, polar protic solvents such as water57'58 and polar aprotic solvents such as dimethylsulfoxide. Krafft has described the rate-accelerating effects of polar coordinating solvents. Acetonitrile had the greatest accelerating

Name Reactions for Carbocyclic Ring Formations

156

effect: CH3CN > EtOAc - THF « Acetone > 1 : 1 THF : CH2C12 > CH2C12 » EtOEt > DMSO.59 Microwave irradiation (MWI) has been reported as an effective way to promote the PKR.60-63 Helaja described the use of MWI to promote the PKR for the synthesis of estrone derivatives, 27a and 27b.60 MWI was equally effective at promoting the PKR as was i-butylmethylsulfide, but that the regioselectivity was inverted. Reaction yields were improved when the target temperature was no greater than 100 °C and the alkyne was added in portions. It was also observed that reaction yields improved, in select instances, when charcoal was added to these MWI reactions. This intermolecular PKR demonstrates the regioselectivity issues observed with un-symmetrical alkene substitution. The location of the carbonyl in the products with respect to the alkene substituents is essentially random. In contrast, the alkyne substituent is only found orto the carbonyl.

27a

Conditions

27b

% Yield

27a : 27b

MW 100 °C, 6x 0.25 eq. Co-Alkyne

57

1.3:1

As Above with charcoal

62

1.3:1

fBuSCH 3

55

1 : 1.6

Billington and Pauson reported on unsuccessful attempts to improve the PKR using ultrasound in 1988.23 Despite this early failure and mixed results in other reports, Kerr has disclosed improved PKRs using highintensity ultrasound in combination with TMANO.64 It was proposed that the standard laboratory ultrasound bath is insufficient to observe the accelerating effect and a high intensity ultrasound source is required. For example, the reaction of phenylacetylene 28 with cycloheptene 29 occurred in 85% yield using high-intensity ultrasound compared with 41% using thermal conditions to provide 30.

Chapter 3 Five-Membered Carbocycles

-^f Co2(CO)6 28

+

Χ~~Λ X '

157

))), TMANO Toluene, 30 min.

29

30

Reactions similar to the PKR that provide cyclopentenones from the [2 + 2 + 1 ] cycloaddition of an alkyne, an alkene, and carbon monoxide can be achieved with metals other than cobalt. Chromium,65 iron, iridium,66'67 molybdenum,68'69 nickel,70 palladium,71 rhodium,72'73 ruthenium,74'75 titanium, tungsten and zirconium ' have all been reported to catalyze the cycloaddition. The mechanism, selectivity, and functional group compatibility varies with each metal, making their discussion beyond the scope of this chapter. Dicobalt octacarbonyl remains a simple and convienent choice for the PKR. The best source and handling of the cobalt catalyst appears to vary, depending on the substrate and the presence of additives. Verdaguer reported no difference in the reaction rate of commercial grade Co2(CO)g versus catalyst purified by sublimation.19 Other precatalyst, such as tetracobalt Qf\ DI

IQ

dodecacarbonyl, have also been used for the PKR. ' ' From the above discussion it is clear that there are a large number of potential reaction conditions. In practice the most common conditions use a slight excess of cobalt octacarbonyl, in acetonitrile or dichloromethane to form the alkyne complex under an atmosphere of nitrogen or argon. The formation of the alkyne complex is easily monitored by thin layer chromatography on silica gel. The alkene and TMANO or NMO are then added and the reaction was allowed to proceed at room temperature until completion. If the results are not satisfactory, the reaction can be optimized with additives or by changing the temperature. In her review, Laschat summarizes the strategies that have been employed to control stereochemistry.1 These strategies include diastereoselectivity from enantiopure starting materials and enantioselectivity with chiral additives. The use of enantiopure starting materials falls into three catagories: The controlling stereocenter is in the tether for an intramolecular PKR, the controlling stereocenter is in a chiral auxiliary on the alkyne or alkene, or a chiral cobalt complex controls stereochemistry. As an example of chirality in the tether, Sezer has demonstrated a strategy for controlling quaternary stereocenters using camphor derived enynes.82 In this system a chair-like transition state, 30, is invoked to explain the stereochemistry at the ring fusion in 31.

158

Name Reactions for Carbocyclic Ring Formations Co(CO)6 S\£ CH2CI2 *NMO 31

30

There are numerous examples of chiral auxiliaries in either the alkyne or alkene producing good stereocontrol. An early example used 2phenylcyclohexanol to form the enantiopure enol ether 32 in a formal total synthesis of (+)-hirsutene.83 This enol ether produced 33a and 33b with 7:1 diastereoselectivity in 55% overall yield. It is noteable that the enol ether is a suitable PKR substrate even though this example predates the milder reaction conditions enabled by the use of additives.

°°2((;ο,β /=^6ρ3η

c=33,

^r

95 °C, 1.5 h 32

33a 7

Similarly, ynol ether 34 gave cyclopentenone 35 in 82% yield and 24:1 diastereoselectivity when 10-(methylthio)isoborneol was used as the chiral auxiliary. When 2-phenylcyclohexanol was used as the chiral auxiliary the observed diastereoselectivity was only 2.5:1. With 10(methylthio)isoborneol it is likely that the sulfur's ability to coordinate the cobalt is contributing to the improved selectivity. norbornadiene Co2(CO)6 34

(OC) 2 Co x Xo(CO) 2

A

Rs

37

P-N

(OC)2Co

J

Co(CO)2 y ^ ^ ~- insertion

'RS

38

Chapter 3 Five-Membered Carbocycles

159

Chiral cobalt complexes have been used to control stereochemistry. A successful strategy described by Verdaguer uses bidentate ligands Diastereomeric cobalt containing phosphorous and sulphur.84"86'133"135 complexes 37 and 38 are formed when an unsymmetrical alkyne cobalt complex is reacted with a chiral ligand. The diastereomers can be separated by chromatography or crystallization to provide enantiopure cobalt complexes. In the PKR the alkene inserts into the least hindered and most reactive cobalt-carbon bond. This bond tends to be adjacent to the smaller alkyne substituent and formed from the cobalt coordinated to sulphur. Thus cyclopentenones are formed in high enantiomeric excess from a single diastereomer. The X group can be carbon, nitrogen or absent. Both sulfides and sulfoxides have been employed. pCH3OPh,

/'-Bu Nx P

pCH 3 OPh-P x

S-TOI

(OC) 2 Co x

Xo(CO) 2 Ph

Pri

Ph

'LL·// NMO, rt, CH2CI2

O

39

(OC)2Co

Co(CO)3

(OC)3Co

Ph

H H 40

Co(CO)2

J v

Rs

R! 41

eni-41

In the case of a symmetric cobalt-alkyne complex, a single enantiomeric complex is formed as in 39. Verdaguer has used enantiopure TV-phosphino-p-tolylsulfinamide (PNSO) ligands to control the absolute stereochemistry to provide 40 in 77% yield and 94% ee.87 There are three critical features of the complex 39: (1) the greater reactivity of the cobalt coordinated to the sulphur versus the cobalt coordinated to the phosphine, and (2) the chiral sulphur atom is directly bound to the reacting cobalt atom and (3) the strong phosphine-cobalt bond. Thus, sulphur determines which metal center reacts and which metal-carbon bond reacts. Phosphorous glues the complex together and deactivates the metal center to which it is attached. Chiral amine TV-oxides have been used to enduce stereocontrol in modest ee (0 to 78%o). The idea is to selectively remove a CO from one of the prochiral cobalts. The desymmetrized complex can then coordinate an alkene as

160

Name Reactions for Carbocyclic Ring Formations

in 41 (or ent-A\) and produce enantiopure products. The first and most successful demonstration of this strategy was reported by Kerr.88 Brucine Noxide promoted the asymmetric PKR of norbornene with tertiary propargyl alcohols. A tertiary alcohol was shown to be required for good ee. Neither propargyl alcohol nor trimethylsilyl-protected alcohol gave any enantiomeric excess. In the best example, dimethylpropynol reacted with norbornene in 63% yield and 78% ee. The use of dimethoxyethane and low temperatures (60 °C) were critical for good ee. Catalytic turnover in the PKR is a goal consistent with green chemistry principles. Most applications of the PKR use stoichiometric cobalt. In-roads for the use of catalytic cobalt have been reported.5 Additives, such as phosphites, alternative sources of cobalt, and other transition metals have been shown to promote the catalytic PKR.89'90 Most of these procedures require an atmosphere of CO or a way to generate CO during the reaction. The proposed role for CO is reaction with liberated Co2(CO)6 to prevent this cobalt species from forming oligomers that terminate the catalytic cycle. Perez-Castells has shown that molecular sieves can be "pre-loaded" with carbon monoxide and used to provide catalytic turnover in the absence of a CO atmosphere.91 The sieves are heated to 200 °C and allowed to cool under CO. The combination of these pretreated sieves and 0.1 equivalent Co2(CO)g gave similar yields to reactions with stoiciometric cobalt. A variety of intermolecular and intramolecular examples were disclosed. Despite these recent advances, a carbon monoxide-free PKR with low or very low cobalt catalyst loading still remains a goal. 3.5.5 3.5.5.1

Synthetic Utility General Utility

The functional group tolerance of the PKR, often predictable stereochemistry and regiochemistry, and recent modifications for improved yields make it an excellent choice for the synthesis of highly functionalized five-membered carbocycles. In general the alkyne partner is more tolerant of substitution than the alkene. Monosubstituted and disubstituted alkynes function in the PKR and both electron donating and electron withdrawing groups are tolerated. Also alkynes tend to produce predictable regioisomers in useful selectivity. The alkene component is more sensitive to both sterics and electronics. In the intermolecular reaction the alkene is typically limited to reactive alkenes such as norbornene. Mono-substituted alkenes can be good substrates but produce 1:1 mixtures of regioisomeric products. Some of these limitations are overcome in the intramolecular PKR. However, this

Chapter 3 Five-Membered Carbocycles

161

reaction is, so far, mostly limited to three or four atom tethers to give 5,5 and 6,5 bicyclic products. General application of the PKR to medium-size ring synthesis remains an aspiration. Alkynes The chemical literature has examples of both monosubstituted and disubstituted alkynes undergoing the PKR. In general, as explained above, the largest alkyne substituent will be in the cc-position of the new cyclopentenone. Exceptions to this "rule" have been observed. For example, Krafft observed that ethyl 2-butynoate reacts with norbornene to place the ester group exclusively in the ß-position of 42.92 Gimbert and Milet have explained this regioselectivity for monosubstituted and disubstituted alkynes as a balance of triple bond polarization and sterics.93 They state that in a polarized alkyne-cobalt complex, the alkynal carbon with the greatest electron density will become the ß-carbon in the PKR product. Thus the PKR with ethyl 2-butynoate gives 42. The electron-rich carbon is adjacent to the ester in the product's ß-position. In the PKR with propyne,14 the methyl group polarizes the alkyne such that the unsubstituted alkyne carbon has the highest electron density and becomes the ß-carbon of the product 43. While it is not intuitive, ethylpropiolate is considered essentially unpolarized in the cobalt complex. In unpolarized complexes, sterics dominate and the larger group occupies the cc-position as in 44. When the steric factors are equalized, electronic influences dominate the PKR to produce 45 as the only product. Krafft has used the propensity for the ester of disubstituted alkynes to prefer the ß-position in her total synthesis of (±)-asteriscanolide.94 C02Et

Alkyl and aryl groups are common alkyne substituents in the PKR. The reaction is compatible with a fully substituted propargyllic position, especially in the intramolecular version. Examples of electron-rich alkynes abound in the PKR, but there are fewer examples of electron-deficient alkynes. Riera and Verdaguer reported a study of electron-deficient alkynes in the PKR with norbornadiene.9 This study clearly demonstrated that both

Name Reactions for Carbocyclic Ring Formations

162

the yield and exo:endo ratio were effected by the nature of the alkyne substituent. The exo-selectivity decreased as the electron-withdrawing ability of the R goup in 46 increased. H

R

M

(oc)3c
,H H 47

co(co)3

46 % Yield

exo : endo

STol

90

100:0

S(0)Tol

50

84:16

S(0)2Tol

52

84:16

C(0)N(CH2CH3)2

85

78:22

C(0)NHAr

92

74:26

Spicer has reported that dimethylacetylene dicarboxylate reacted with norbornene at room temperature in the presence of TMANO to give the cyclopentenone in 73% yield.96 However, the cobalt complex is thermally unstable and mild PKR conditions were required for success. The intramolecular and inter-molecular PKR of alkynones has been reported by Hoye in 30-90% yields.97 In the intramolecular examples, improved yields were observed when a geminai dimethyl was incorporated into the tether. In the intermolecular examples, the ketone was found in the ß-position of the cyclopentenone. The vinylogous 48 ynone cyclised in 62% yield to provide the tricyclic product 49 as a 2.7:1 mixture of cis/trans isomers. An interesting intramolecular example was disclosed by de Meijere in which ketone 50 produced the spirocyclopropane 51 in 63% yield.98

tfcó-· TMS

r ^ - ^ ^

T M S

Co2(CO)8 CH3CN 75 °C, 6h

48

H

H

eis- 49

TMS

Chapter 3 Five-Membered Carbocycles

163

Co2(CO)8 TMANO CH2CI2 20 °C, 1 h 63%

Thus, under the appropriate conditions, the alkyne partner does not appear to be severly limited by electronics or sterics. It is important that the regiochemstry of the alkyne substituents in the products can be predicted with some confidence. The same cannot be said for the alkene. Alkenes R

L

R

L

V;Co(CO)3 R s^Co-(CO) 2

V?Co(CO)3 R s - f bo-(CO)2

EWG

EWG

I-4

52

►

The subject of alkene reactivity in the intermolecular PKR has been reviewed by Gibson. She points out several important issues related to reactivity and regiochemistry. With respect to reactivity, it is wellknown that the intermolecular PKR requires a reactive alkene to proceed in useful yields. Gibson compares the reported reactivity to the predicted reactivity calculated from the LUMOs by Milet and Gimbert.99'100 She concludes that the LUMO predictions are a useful tool for predicting alkene reactivity; a lower lying LUMO is associated with a more reactive alkene. One caveat is that the alkene does not enter a non-PKR reaction manifold. For example, dienes and vinylesters are expected to have low lying LUMOs, but tend to be poor PKR substrates. These alkenes often engage in other reactions under the PKR conditions. The reactivity of electron deficient alkenes has been reviewed by Carretero.12 In general, α,β-unsaturated nitriles, ketones and esters are poor substrates for the PKR. It is hypothesized that the cobaltacycle intermediate 1-4 undergoes ß-hydride elimination to give 52 faster than carbon monoxide insertion. Dienes 53 result from this alternative pathway. Cazes has shown that vinyl esters and sulfones participate in the intermolecur PKR under mild conditions: 0-20 °C and 6 equivalents of NMO.101 The yields ranged from 0 to 59% for the esters and 49 to 71% for the sulfones. Acrylonitrile gave

164

Name Reactions for Carbocyclic Ring Formations

complex mixture of products under these same conditions. Cyclopent-2enone, cyclohex-2-enone and methylvinyl-ketone were unreactive. Chung has taken advantage of the difference in alkene reactivities to perform a one-pot PKR/Diels-Alder reaction.102 The reaction combined a 2:1:3 mixture of norbornene, 1-ethynylcyclohexene and dimethylfumarate, respectively. A 90% yield of the pentacyclic products 54 and 55 were formed in a 1.1:1 ratio.

J

R

R = C02CH3

cat. Co(CO)8 CO 30 atm 130 °C 21 h 90%

Vinyl sulfones are good substrates for the PKR. Evans has reported the stereoselective PKR of 56 to form 57 in studies directed toward kinabalurine alkaloids.103

S02Ph

NMOH 2 0

*0 °C to room T 15h 73%

TsN 57

The bond angle of cycloalkenes can be used to estimate the LUMO and predict reactivity. Smaller bond angles correlate with lower LUMOs and greater reactivity. Thus the bond angles and reactivities for cycloalkenes follow the same order: cyclopropene > cyclobutene > cyclopentene = norbornene > cycloheptene = cyclooctene > cyclohexene. Cyclopropene is the most reactive and cyclohexene is the least reactive. Thus proper choice of substrates and conditions can produce useful products via the intermolecular PKR. For example, Pericàs recently described the preparation of amino acid derivitives using the PKR, 58 to 59.104 Unfortunately, the amino acid stereocenter was too removed from the newly formed stereocenters to provide any asymmetric induction. The products were isolated as 1:1 mixtures of diastereomers that required chiral HPLC for separation. Despite the low yields observed in the PKR (18^17%),

Chapter 3 Five-Membered Carbocycles

165

the method shows promise as a way to assemble peptide-like scaffolds from readily available starting materials.

.Λ

Ph

DMSO

Co 2 (CO) 6

1,2-DCE 83 °C, 24 h

Unlike the more predictable regiochemistry for alkynes, monosubstituted or differentially disubstituted alkenes give 1:1 mixtures of regio-isomers as shown for the synthesis of the estrone derivatives 27a and 27b above. Krafft addressed the issue of regioselectivity by introducing a group into the alkene to coordinate cobalt. 105_, ° 7 Coordination significantly increased the regioselectivity and the reactivity of the alkene. In her examples, a homoallylic sulphur or amine, 61, gave the best results. Allylic or bishomoallylic heteroatoms gave modest regioselectivity. Alcohols and ethers did not provide any ligand directed regioselectivity. Kerr has shown that diethyl allylphosphonate 63 also provides ligand directed regioselectivity in the PKR when a combination of dichloromethane and acetonitrile is used as the solvent. 108 Tethers containing multiple hetereoatoms 107 and aryl dimethylamino 109,110 ' groups have been used to take advantage of this directing effect, 64 and 65, respectively. O

Co2(CO)6

90 °C

+

Toluene, 30 h

Ph-

61

60

tf 62a

% Yield

O

\ +

Ph-

Λ

V62b

62a : 62b

SCH3

61 %

18: 1

N(CH3)2

72%

5: 1

Name Reactions for Carbocyclic Ring Formations

166

EtO * 0 EtO |

^ Ν ^ (O)S

Ì

L = N(CH3)2 or SEt 63

64

65

As described above, a temporary tether has also been used to control regiochemistry and enhance reactivity. The improved yields observed with intramolecular versus intermolecular PKRs have encouraged attempts to facilitate the reaction with a cleavable tether that contains ether or silyl groups.46"51 The intramolecular PKR has seen the most application for synthesis. There are numerous examples of the formation of carbocyclic and heterocyclic systems. Recent applications show that the PKR is useful for building complex, bridged ring systems. Martin has disclosed 6 examples, 66a-f, of nitrogen bridged bicyclic heterocycles in modest to excellent yield from the PKR.111 Several common promoters (NMO, BuSMe and 4 A molecular sieves) were tried before finding optimum conditions. Stepwise reaction by first forming the cobait-alkyne complex then adding six equivalents of DMSO as a promoter provided the best conditions. Also, the Co2(CO)8 catalyst gave the best results when handled and stored under argon. These conditions were applied to a total synthesis of alstonerine (vida infra).

H

Κ^ U> Λ Κ^ ξ& ^ ι

Y

v vN-,

ο

66a (89%)

H

ι

Υ

,,Ν,,

ο

H—7—( LN,\

i

,νΝ,, OTBS

66b (91%) 66c (33%) 66d (69%)

ι

,,Ν,,

i

,.Ν,,

ι R R = Me or Bn 66e (>80%) 66f(74%)

An underused property of cobalt-coordinated alkynes is the stabilization of propargyllic cations. The Nicholas reaction is a propargylic substitution reaction facilitated by the ability of the adjacent cobalt complex to stabilize the propargylic cation, 67 to 68. Both carbon and heteroatom nucleophiles have been used to effect this transformation.112-114 This transformation has been been used as a strategy to introduce the alkene component for an intramolecular PKR.115 Shea has probed the use of an

Chapter 3 Five-Membered Carbocycles

167

intramolecular-endocyclic-Nicholas PKR sequence for the formation of tricyclic heterocycles, 69 to 71. 116 The reactions are classified as endocyclic because the cobalt complex is in the ring formed in the Nicolas reaction, 70. Various ring sizes (m,n) and nucleophiles (X) were tried. When the nucleophile was an alcohol or a sulphonamide the final tricyclic products were obtained. Acids (XH = CO2H) gave poor yields in the Nicholas reaction, and the ester intermediates failed to undergo the PKR. For the ethers, the [5,7,5] and [5,8,5] ring systems formed in good yield, the [5,6,5] and [5,9,5] systems formed in poor yield and the [5,8,6] system produced no identifiable products. Both the yields and disatereoselectivities varied with the conditions. The sulfonamides were limited to [5,7,5] and [5,8,5] systems. The [5,7,5] ring system 73b, containing the sulphonamide, formed in exceptional yield and diastereoselectivity. (OC)3Co-Co(CO)3

(OC) 3 Co-Co(CO) 3

Acid

Nu = allylborane, amide, thiophene, etc.

Nu 67 (OC)3Cor£o(CO)3

BF3>QEt2

72a

(OC)3Co-Co(CO)3

73a

72b

p(
°

^

73b % Yield a / b

PKR Conditions

Products

CyNH2, Heat

72a / 72b

38/53

NMO

72a / 72b

22/9

CyNH2, Heat

73a / 73b

0/98

168

Name Reactions for Carbocyclic Ring Formations

An alternative method to take advantage of the activating nature of the cobalt alkyne was demonstrated by Smit and Caple.117 In this strategy, a cobalt coordinated eneyne 74 is acylated with ethyltetrafluoroborate and the intermediate cation is captured with allyl alcohol to provide the starting material for an intramolecular PKR, 75. Heating in hexane provided the desired tricyclic product 76 in 45% yield. It should be noted that the PKR portion of this sequence predates many of the improved conditions.

^Co2(CO)6

Co 2 (CO) 6 (1)EtC(0)BF 4

60 °C »~

4h hexane 74

3.6.5.2

75(71%)

76 (45%)

Applications in total synthesis

The ability to predict regiochemistry, a rapid increase in synthetic complexity, and the frequency of 5-membered rings in synthetic targets has made this reaction the focus of numerous synthetic studies. The PKR has been applied to the synthesis of many natural products: (±)-pentalenene,118 (+)-hirsutene,82 (-)-kainic acid,119 (+)-brefeldin A,120 (+)-epoxydictymene,121 (±)-asteriscanolide, (±)-oc- and ß-cedrene, 122 Japanese Hop Ether, 123,124 (-)" 127 125,111 , x · ·,,· 126 (-)-incarvilline,lzo paecilomycine,'z/ and (+)-(Xalstonerine 1 ^'"', 8 The Scheme on page 169 shows the PKR disconnections skytanthine. used to assemble these natural products. The wavy blue lines indicate bonds formed from the PKR. Mukai accomplished the stereosective synthesis of three lycopodium alkaloids (-)-magellanine, (+)-magellaninone, and (+)-paniculatine from a Their strategy employed the use of two common intermediate.129 intramolecular PKRs to build a tetracyclic intermediate from acyclic starting material; diethyl L-tartrate.

Chapter 3 Five-Membered Carbocycles

169

C02H N H

0

"//

HÖ H H

(+)-brefeldin A

vtL bond formed in Nicholas reaction

(+)-epoxydictymene

.0

(±)-asteriscanolide

or

(±)-a-cedrene

(±)-ß-cedrene

MA?

Japanese hop ether

H \\

(-)-alstonerine

HO' C.

C=0 (-)-magellanine R=OH,R'=H (+)-magellaninone R+R'=0 H,C

OH paecilomycine A

C02H

/

H

N H

bH 3

(+)-a-skytanthine

(+)-paniculatine

Name Reactions for Carbocyclic Ring Formations

170

In the synthesis of (±)-pentalenene, the PKR was used to construct the angularly fused triquinane ring system 77 from cyclopentene 76.

The allylic methyl group in 76 successful directs the bulky cobaltalkyne complex to the opposite face of the cyclopentene with 8:1 diastereoselectivity. It is notable that, even in the absence of additives, this intramolecular PKR with a trisubstituted alkene provides useful yields of product. In a more recent application of this allylic directing effect, Dake prepared an advanced intermediate for a potential Fusicoccane synthesis.130 In his example the allylic position was a quaternary center and excellent, reproducible yields were obtained for the PKR. The observed stereochemistry of the ring fusion was consistent with the Magnus model. The larger of the two allylic groups in 78 prefered the exo face of the newly formed ring system, syn to the hydrogen at the ring fusion.

R

^0°' } f Co2(CO)8 R r\=== -

L^^

NMO

78

R

>*0

^ 79a

CH3

+

R

Μ^Λ CH3 79b

% Yield

79a : 79b

R = CH3

89

6.1 : 1

R = CH2CH3

84

1.3: 1

79

2.2: 1

Protectinq GrouD

-O

In an attempt to improve the selectivity for the desired isomer 79a, the protecting group was varied. The expectation was that a larger protecting group would increase the selectivity for the desired isomer. It is surprising that as the size of the acetonide increased the selectivity decreased. No

Chapter 3 Five-Membered Carbocycles

171

explanation for this observation was offered. It is interesting to constrast this result with Honda's in the synthesis of (+)-a-skytanthine where, again, a simple methyl group in 80 provides the desired diastereomer 81 in 71% isolated yield. H3C Co2(CO)8 ^TMANO

NsN

81

80

Notice that under the best PKR conditions the nosyl nitro group was reduced to the amine. When the reaction was performed in the absence of a hydrogen source reduction still occurred. The exact mechanism of the reduction remains unclear, but the transition metal-catalyzed reduction of nitro groups with CO is well documented.131,132 The disconnections shown for (+)-brefeldin A suggest the use of an intramolecular cyclization to close the macrocycle. In fact, the cyclopentene was formed via an intermolecular PKR/retro-Diels-Alder sequence (82 goes to 83) to take advantage of the high reactivity of norbornadiene in the PKR. Furthermore, a new cyclopentenone is revealed by the retro-Diels-Alder reaction so that PKR product 84 is a synthetic equivalent for cyclopentadienone 85.

H

H H

OTBDMS

82

CH3AICI2

H

maleic anhydride 66% OTBDMS

83

It should be noted for (+)-epoxydictymene the carbon derived from carbon monoxide is not contained in the final product. This carbon is removed after the PKR in a subsequent ring opening. Also of interest is the author's use of a Nicholas reaction to close the 8-member ring. After

172

Name Reactions for Carbocyclic Ring Formations

significant optimization, conditions were found that converted allyl silane 86 to 87 in excellent yield and diastereoselectivity. The diastereomer 87 was favored more than 20:1 over its isomer even though the acetal in 86 existed as a 1:1 mixture. (CO)6Cp

.(CO)6Co TMSOTf Et20 ^. -78 °C 15 min 91% 87

The optimization of the PKR for forming the bridged bicyclic core of (-)-alstonerine was discussed above. The eneyne 88 employed in the successful synthesis was available in enantiopure form from trytophan in four steps. Neither the unprotected indole nitrogen nor the additional sp2 centers in the piperidine ring adversely affected the PKR. Under the optimized conditions, the desired compound 89 was isolated in 92% yield as a single diastereomer.

1.2 eq Co2(CO)8 NCbz then 6 eq DMSO THF, 65 °C 89 (92%)

The syntheses of (-)-alstonerine, (+)-epoxydictymene, and kainic acid all exemplify a strategy of cyclization followed by oxidative ring-opening. For (+)-epoxydictymene, the cyclopentenone is reduced and hydroxylated to 90. This triol is then opened to provide aldehyde 91. The carbon originally derived from carbon monoxide is thus lost from the substrate. In (-)alstonerine the cyclopentenone was converted to the aldehyde 92 in a twostep procedure. First, the sily enol ether was formed with /-propylsilyl hydride in the presence of a platinum catalyst. The double bond was then cleaved using catalytic OsÜ4 with NaI04. Takano demonastrates a third ring opening strategy in the synthesis of (-)-kainic acid. A Baeyer-Villiger oxidation is affected with five equivalents of m-CPBA to convert ketone 93 to lactone 94. Thus these syntheses demonstrate methods to expand the use of the PKR beyondfive-memberedrings.

Chapter 3 Five-Membered Carbocycles

173

Pb(OAc)4

OTIPS

CHO

C02CH3

Krafft effectively uses both electronic and steric effects to fully control the PKR regioselectivity in her synthesis of (±)-asteriscanolide. As discussed above, electron-withdrawing groups on the alkyne favor the ßposition in the cyclopentenone, while sterically demanding groups favor the α-position. Complete control of regiochemistry was observed in the intermolecular PKR to form intermediate 96 from 95. The methyl group derived from propene was observed only alpha to the carbonyl. Because asteriscanolide contains a geminai dimethyl group at this alpha position, PKRs with isobutene and allylic thioalkyl groups were attempted. However, no cycloaddition was obtained with these alkenes and the second methyl group was installed by deprotenation and alkylation in 92% yield.

EtOoC—Ξ^Co(CO)6 95

ÒTBDMS

NMO, CH2CI2 propene 89%

Et02C

96

OTBDMS

174

Name Reactions for Carbocyclic Ring Formations

Kerr's syntheses of (±)-a- and ß-cedrene are examples of using the PKR to construct compact brigded ring systems from readily available starting materials. This is another example of a trisubstituted alkene reacting well in an intramolecular PKR. As seen previously, the olefin geometry in the starting material 97 is transmitted with high fidelity to the α-keto methyl group in 98. The ketone 98 was epimerized with lithium hydroxide in a mixture of tetrahydrofuran and water to provide a 9:1 ratio in favour of the desired isomer.

(OC)6Co 97 2:1

98 2:1

Japanese Hop Ether has been prepared by both an intermolecular PKR123 and an intramolecular PKR.24 In Kerr's intramolecular version, it was demonstrated that the use of mild conditions (room temperature) allows the double bond stereochemistry to be transmitted to the product with high fidelity: (E)-99 gives exclusively 100 and (Z)-99 gives exclusively 101. Further manipulation transforms 101 into Japanese Hop Ether. Co(CO)6

(£)-99

TMANO2H20 »OTHP acetone 66%

3R100

OTHP

Co(CO)6

(Z)-99

ΤΜΑΝΟ·2Η20 *acetone OTHP 90%

There are few examples where the absolute stereochemistry is determined in the PKR. Verdaguer has demonstrated the use of a bidentate phosphorous-sulphur ligand to provide an enantiopure cyclopentenone in for the synthesis of the HIV drug (-)-abacavir.133-135 The achiral alkyne cobalt complex is generated first in 1 h at room temperature. Heating with enantiopure P.S-ligand 102 provides a separable mixture of diastereomeric

Chapter 3 Five-Membered Carbocycles

175

alkyne complexes 103a and 103b. Reaction of one of these complexes with norbornadiene gave compound 104 in 53% overall yield and greater than 99% enantiomeric excess. This compound was further manipulated to provide the HIV drug (-)-abacavir.

TMS

Phs

1)Co 2 (CO) 8

2) Bu

,S®

Ph-Px

PPh2

N

Ρ

S-ÌBU

(CO) 2 Co x Xo(CO) 2 W TMS

I

102

Bn Ν^

Bn

—*-

o

(CO)2Co

H

H

Xo(CO) 2 TMS 103b

103a

TMS 103

Bn Ph Nx P Ph->' S^fflu

— H7N

104 (53% yield, > 99% ee)

ώα N

o, N

(-)-abacavir

Ί

OH

As shown above, the PKR has tremendous synthetic potential due to a rapid increase in synthetic complexity from simple starting materials. The frequent presence of five-membered rings in synthetic targets has led to numerous applications. In turn, these applications have inspired improved conditions that allow the PKR to occur under mild conditions with with predictable regiocontrol and stereocontrol. Efforts continue to optimize the reaction for improved alkene regiocontrol, absolute stereocontrol, expanded substrate scope (especially for unreactive alkenes and medium-size ring formation) and catalytic turnover. From the above reactions, it is clear that there are a large number of potential reaction conditions. In practice the most common conditions use a slight excess of cobalt octacarbonyl, in acetonitrile or dichloromethane to form the alkyne complex under an atmosphere of nitrogen or argon. The formation of the alkyne complex is easily monitored by thin layer chromatography on silica gel. The alkene and TMANO or NMO are then added, and the reaction was allowed proceed at room temperature until complete. If the results are not satisfactory, the reaction can be optimized with additives or by changing the temperature. An experimental example is provided below. If absolute stereocontrol is desired, the reader is encouraged

176

Name Reactions for Carbocyclic Ring Formations

to use the examples sited above as a starting point for the best experimental conditions. 3.5.6

Experimental

TsN^^S^ 105

(1)Co 2 (CO) 8 , CH 2 CI 2 room temperature 1.5 h ► TsN (2) N M O H 2 0 , 0 °C to room temperature 15 h, 87%

106

(±)-7-Methyl-2-(toluene-4-sulfonyl)-l,2,3,4,4a,5-hexahydro-[2]pyrindin6-one 106103 At room temperature a solution of the enyne 105 (824 mg, 2.97 mmol, 1 equiv) in dichloromethane (100 mL, 0.029 M) was degassed with a steady stream of N 2 for approximately 0.5 h. Co2(CO)8 (1.52 g, 4.45 mmol, 1.5 equiv) was added in one portion. Stirring was continued for 1.5 h before TLC analysis indicated the formation of the cobalt complex [brown spot; R/~ 0.9 (cyclohexane-EtOAc; 1:1)]. The solution was cooled to 0 °C before ΝΜΟΉ2Ο (2.60 g, 19.26 mmol, 6.5 equiv) was added in two portions. Stirring was continued at 0 °C to room temperature overnight. Silica (ca. 12 g) was added, the solvent was removed under reduced pressure and the residue purified by flash column chromatography (cyclohexane-EtOAc; 1:1) to afford the colourless solid 106 (790 mg, 87%); mp = 116 °C; R/ = 0.35 (cyclohexane-EtOAc; 1:1). 3.5.7

References

1. 2.

[R] Laschat, S.; Becheanu, A.; Bell, T.; Baro, A. Synlett 2005, 2547-2570. [R] Blanco-Urgoiti, J.; Anorbe, L.; Perez-Serrano, L.; Dominguez, G.; Perez-Castells, J. Chem. Soc. Rev. 2004, 33,12-A2. [R]Struebing, D.; Beller, M. Top. Organomet. Chem. 2006, 75,165-178. [R] Brummond, K. M.; Kent, J. L. Tetrahedron 2000, 56, 3263-3283. [R] Gibson, S. E.; Stevenazzi, A. Chem., Int. Ed. 2003, 42, 1800-1810. [R] Geis, O.; Schmalz, H.-G. Angew. Chem., Int. Ed. 1998, 37, 911-914. [R] Schore, N.E. Org. React. (N. Y.) 1991, 40, 1-90. [R] Schore, N. E. Chem. Rev. 1988, S8, 1081-119. [R] Gibson, S. E.; Mainolfi, N. Angew. Chem., Int. Ed, 2005, 44, 3022-3037. [R] Sugihara, T.; Yamaguchi, M.; Nishizawa, M. Chem. Eur. J. 2001, 7, 1589-1595. [R] Ingate, S. T.; Marco-Contelles, J. Org. Prep. Proced. Int. 1998, 30, 121-143. [R] Rivero, M. R.; Adrio, J.; Carretero, J. C. Eur. J. Org. Chem. 2002, 2881-2889. Pauson, P. L.; Khand, I. U.; Knox, G. R.; Watts, W. E. J. Chem. Soc. D 1971, 36. Khand, I. U.; Knox, G. R.; Pauson, P. L.; Watts, W. E.; Foreman, M. I. J. Chem. Soc, Perkin Trans. 7 1973,977-981. Magnus, P.; Principe, L. M. Tetrahedron Lett. 1985,26,4851^854.

3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15.

Chapter 3 Five-Membered Carbocycles 16. 17. 18. 19. 20. 21. 22. 23. 24. 25. 26. 27. 28. 29. 30. 31. 32. 33. 34. 35. 36. 37. 38. 39. 40. 41. 42. 43. 44. 45. 46. 47. 48. 49. 50. 51. 52. 53. 54.

177

La Belle, B. E.; Knudsen, M. J.; Olmstead, M. M.; Hope, H.; Yanuck, M. D.; Schore, N. E. J. Org. Chem. 1985, 50, 5215-5222. Yamanaka, M.; Nakamura, E. J. Am. Chem. Soc. 2001,123, 1703-1708. Pericas, M. A.; Balsells, J.; Castro, J.; Marchueta, I.; Moyano, A.; Riera, A.; Vazquez, J.; Verdaguer, X. Pure Appi. Chem. 2002, 74, 167-174. Cabot, R.; Lledo, A.; Reves, M.; Riera, A.; Verdaguer, X. Organometallics 2007, 26, 1134— 1142. Banide, E. V.; Mueller-Bunz, H.; Manning, A. R.; Evans, P.; McGlinchey, M. J. Angew. Chem., Int. Ed. 2007, 46, 2907-2910. [R] Bonaga, L. V. R.; Kraffl, M. E. Tetrahedron 2004, 60, 9795-9833. Camps, F.; Moreto, J. M.; Ricart, S.; Vinas, J. M. Angew. Chem. 1991, 103, 1540-1542 (See also Angew Chem., Int. Ed. Engl. 1991, 11, 1470-1472). Billington, D. C; Helps, I. M.; Pauson, P. L.; Thomson, W.; Willison, D. J. Organomet. Chem. 1988, 354, 233-242. Simonian, S. O.; Smit, W. A.; Gybin, A. S.; Shashkov, A. S.; Mikaelian, G. S.; Tarasov, V. A.; Ibragimov, 1.1.; Caple, R.; Froen, D. E. Tetrahedron Lett. 1986, 27, 1245-1248. Smit, W. A.; Gybin, A. S.; Shashkov, A. S.; Strychkov, Y. T.; Kyz'mina, L. G.; Mikaelian, G. S.; Caple, R.; Swanson, E. D. Tetrahedron Lett. 1986, 27, 1241-1244. Shambayati, S.; Crowe, W. E.; Schreiber, S. L. Tetrahedron Lett. 1990,31, 5289-5292. Jeong, N.; Chung, Y. K.; Lee, B. Y.; Lee, S. H.; Yoo, S. E. Synlett 1991, 204-206. Kerr, W. J.; Lindsay, D. M.; Kerr, W. J.; Lindsay, D. M. Chem. Commun. 1999, 2551-2552. Brown, D. S.; Campbell, E.; Kerr, W. J.; Lindsay, D. M.; Morrison, A. J.; Pike, K. G.; Watson, S. P. Synlett 2000, 1573-1576. [R] Sugihara, T.; Yamaguchi, M.; Nishizawa, M. Rev. Heteroat. Chem. 1999,21, 179-194. Sugihara, T.; Yamaguchi, M.; Nishizawa, M. Chem.-Eur. J. 2001, 7, 1589-1595. Perez del Valle, C; Milet, A.; Gimbert, Y.; Greene, A. E. Angew. Chem., Int. Ed. 2005, 44, 5717-5719. Chung, Y. K.; Lee, B. Y.; Jeong, N.; Hudecek, M.; Pauson, P. L. Organometallics 1993, 12, 220-223. Whitby, R. J.; Dixon, S.; Maloney, P. R.; Delerive, P.; Goodwin, B. J.; Parks, D. J.; Willson, T. M. J. Med Chem. 2006, 49, 6652-6655. Rajesh, T.; Periasamy, M. Tetrahedron Lett. 1998, 39, 117-118. Sugihara, T.; Yamada, M.; Ban, H.; Yamaguchi, M.; Kaneko, C. Angew. Chem., Int. Ed. Engl. 1998,36, 2801-2804. Kraffl, M. E.; Bonaga, L. V. R.; Hirosawa, C. J. Org. Chem. 2001, 66, 3004-3020. Sugihara, T.; Yamada, M.; Yamaguchi, M.; Nishizawa, M. Synlett 1999, 771-773. Tang, Y.; Deng, L.; Zhang, Y.; Dong, G.; Chen, J.; Yang, Z. Org. Lett. 2005, 7, 593-595. Petrovski, Z.; Romao, C. C; Afonso, C. A. M. Synth. Commun. 2008, 38, 2761-2767. Hernandez-Rodriguez, M.; Avila-Ortiz, C. G.; del Campo, J. M.; Hernandez-Romero, D.; Rosales-Hoz, M. J.; Juaristi, E. Aust. J. Chem. 2008, 61, 364-375. Sugihara, T.; Yamaguchi, M. Synlett 1998, 1384-1386. Perez-Serrano, L.; Blanco-Urgoiti, J.; Casarrubios, L.; Dominguez, G.; Perez-Castells, J. J. Org. Chem. 2000, 65, 3513-3519. Blanco-Urgoiti, J.; Casarrubios, L.; Dominguez, G.; Perez-Castells, J. Tetrahedron Lett. 2002, 43, 5763-5765. Son, S. U.; Lee, S. I.; Chung, Y. K. Angew. Chem., Int. Ed. 2000, 39, 4158^1160. Muto, R.; Ogasawara, K. Tetrahedron Lett. 2001, 42,4143-4146. Marco-Contelles, J.; Ruiz, J. Tetrahedron Lett. 1998,39, 6393-6394. Reichwein, J. F.; Iacono, S. T.; Patel, M. C;-Pagenkopf, B. L. Tetrahedron Lett. 2002, 43, 3739-3741. Reichwein, J. F.; Iacono, S. T.; Pagenkopf, B. L. Tetrahedron 2002, 58, 3813-3822. Ishaq, S.; Porter, M. Synth. Commun. 2006,36, 547-557. Dobbs, A. P.; Miller, I. J.; Martinovic, S. Beilstein J. Org. Chem. 2007, 3. Madu, C. E.; Lovely, C. J. Synlett 2007,2011-2016. Madu, C. E.; Seshadri, H.; Lovely, C. J. Tetrahedron 2007, 63, 5019-5029. Lovely, C. J.; Seshadri, H.; Wayland, B. R.; Cordes, A. W. Org. Lett. 2001, 3, 2607-2610.

178 55. 56. 57. 58. 59. 60. 61. 62. 63. 64. 65. 66. 67. 68. 69. 70. 71. 72. 73. 74. 75. 76. 77. 78. 79. 80. 81. 82. 83. 84. 85. 86. 87. 88. 89. 90.

Name Reactions for Carbocyclic Ring Formations Mastrorilli, P.; Nobile, C. F.; Paolillo, R.; Suranna, G. P. J. Mol Catal. A: Chem. 2004, 214, 103-106. Becheanu, A.; Laschat, S. Synlett 2002, 1865-1867. Krafft, M. E.; Wright, J. A.; Bonaga, L. V. R. Tetrahedron Lett. 2003, 44, 3417-3422. Krafft, M. E.; Wright, J. A.; Bonaga, L. V. R. Can. J. Chem. 2005,83, 1006-1016. Krafft, M. E.; Scott, I. L.; Romero, R. H.; Feibelmann, S.; Van Pelt, C. E. J. Am. Chem. Soc. 1993,115, 7199-7207. Fager-Jokela, E.; Kaasalainen, E.; Leppaenen, K.; Tois, J.; Helaja, J. Tetrahedron 2008, 64, 10381-10387. Iqbal, M; Vyse, N.; Dauvergne, J.; Evans, P. Tetrahedron Lett. 2002, 43, 7859-7862. Fischer, S.; Groth, U.; Jung, M.; Schneider, A. Synlett 2002, 2023-2026. Iqbal, M.; Duffy, P.; Evans, P.; Cloughley, G.; Allan, B.; Lledo, A.; Verdaguer, X.; Riera, A. Org. Biomol. Chem. 2008, 6, 4649-4661. Ford, J. G.; Kerr, W. J.; Kirk, G. G.; Lindsay, D. M.; Middlemiss, D. Synlett 2000, 14151418. Jordi, L.; Segundo, A.; Camps, F.; Ricart, S.; Moreto, J. M. Organometallics 1993,12, 3795— 3797. Shibata, T.; Takagi, K. J. Am. Chem. Soc. 2000,122, 9852-9853. Shibata, T.; Toshida, N.; Yamasaki, M.; Maekawa, S.; Takagi, K. Tetrahedron 2005, 61, 9974-9979. Moradov, D.; Al Quntar, A. A. A.; Youssef, M.; Smoum, R.; Rubinstein, A.; Srebnik, M. J. Org. Chem. 2009, 74, 1029-1033. Maji, P.; Wang, W.; Greene, A. E.; Gimbert, Y. J. Organomet. Chem. 2008, 693, 1841-1849. Zhang, M.; Buchwald, S. L. J. Org. Chem. 1996, 61,4498^1499. Lan, Y.; Deng, L.; Liu, J.; Wang, C; Wiest, O.; Yang, Z.; Wu, Y.-D. J. Org. Chem. 2009, 74, 5049-5058. Kim, D. E.; Lee, B. H.; Rajagopalasarma, M; Genet, J.-P.; Ratovelomanana-Vidal, V.; Jeong, N. Adv. Synth. Catal. 2008,350, 2695-2700. Hayashi, Y.; Miyakoshi, N.; Kitagaki, S.; Mukai, C. Org. Lett. 2008,10, 2385-2388. Kondo, T.; Suzuki, N.; Okada, T.; Mitsudo, T. J. Am. Chem. Soc. 1997,119, 6187-6188. Itami, K.; Mitsudo, K.; Fujita, K.; Ohashi, Y.; Yoshida, J. J. Am. Chem. Soc. 2004, 126, 11058-11066. Zhao, Z.; Ding, Y.; Zhao, G. J. Org. Chem. 1998, 63, 9285-9291. Garcia-Garcia, P.; Fernandez-Rodriguez, M. A.; Rocaboy, C; Andina, F.; Aguilar, E. J. Organomet. Chem. 2008, 693, 3092-3096. Takahashi, T.; Xi, Z.; Nishihara, Y.; Huo, S.; Kasai, K.; Aoyagi, K.; Denisov, V.; Negishi, E. Tetrahedron 1997, 53, 9123-9134. Chen, C; Liu, Y.; Xi, C. Tetrahedron Lett. 2009, 50, 5434-5436. Paolillo, R.; Gallo, V.; Mastrorilli, P.; Nobile, C. F.; Rose, J.; Braunstein, P. Organometallics 2008,27,741-746. Arias, J. L.; Cabrera, A.; Sharma, P.; Rosas, N.; Sampere, R. J. Mol. Catal. A: Chem. 2006, 24(5,237-241. Sezer, S.; Guemruekcue, Y.; Sahin, E.; Tanyeli, C. Tetrahedron: Asymmetry 2008, 19, 2705-2710. Castro, J.; Sorensen, H.; Riera, A.; Morin, C; Moyano, A.; Pericas, M. A.; Greene, A. E. J. Am. Chem. Soc. 1990,112, 9388-9389. Reves, M.; Achard, T.; Sola, J.; Riera, A.; Verdaguer, X. J. Org. Chem. 2008, 73, 70807087. Lledo, A.; Sola, J.; Verdaguer, X.; Riera, A.; Maestro, M. A. Adv. Synth. Catal. 2007, 349, 2121-2128. Ferrer, C; Riera, A.; Verdaguer, X. Organometallics 2009, 28,4571^1576. Ji, Y.; Riera, A.; Verdaguer, X. Org. Lett. 2009,11,4346-4349. Kerr, W. J.; Lindsay, D. M.; Rankin, E. M.; Scott, J. S.; Watson, S. P. Tetrahedron Lett. 2000, 41, 3229-3233. Jeong, N.; Hwang, S. H.; Lee, Y.; Chung, Y. K. J. Am. Chem. Soc. 1994,116, 3159-3160. [R] Shibata, T., Adv. Synth. Catal. 2006, 348, 2328-2336.

Chapter 3 Five-Membered Carbocycles 91. 92. 93. 94. 95. 96. 97. 98. 99. 100. 101. 102. 103. 104. 105. 106. 107. 108. 109. 110. 111. 112. 113. 114. 115. 116. 117. 118. 119. 120. 121. 122. 123. 124. 125. 126. 127. 128. 129. 130. 131. 132.

179

Blanco-Urgoiti, J.; Casarrubios, L.; Dominguez, G.; Perez-Castells, J. Tetrahedron Lett. 2002, 43, 5763-5765. Krafft, M. E.; Romero, R. H.; Scott, I. L. Synlett 1995, 577-578. de Bruin, T. J. M.; Michel, C; Vekey, K.; Greene, A. E.; Gimbert, Y.; Milet, A. J. Organomet. Chem. 2006, 691, 4281^288. Krafft, M. E.; Cheung, Y.-Y.; Juliano-Capucao, C. A. Synthesis 2000, 1020-1026. Sola, J.; Riera, A.; Pericas, M. A.; Verdaguer, X.; Maestro, M. A. Tetrahedron Lett. 2004, 45, 5387-5390. Baxter, R. J.; Knox, G. R.; Pauson, P. L.; Spicer, M. D. J. Organomet. Chem. 1999, 579, 9096. Hoye, T. R.; Sudano, J. A. J. Org. Chem. 1993, 58, 1659-1660. de Meijere, A.; Becker, H.; Stolle, A. Kozhushkov, S. I.; Bes, M. T.; Salauen, J.; Noltemeyer, M., Chem. Eur. J. 2005,11, 2471-2482. de Bruin, T. J. M.; Milet, A.; Greene, A. E.; Gimbert, Y. J. Org. Chem. 2004, 69, 1075-1080. de Bruin, T. J. M.; Milet, A.; Robert, F.; Gimbert, Y.; Greene, A. E. J. Am. Chem. Soc. 2001, 723,7184-7185. Ahmar, M.; Antras, F.; Cazes, B. Tetrahedron Lett. 1999, 40, 5503-5506. Kim, D. H.; Chung, Y. K. Chem. Commun. 2005, 1634-1636. Kavanagh, Y.; O'Brien, M.; Evans, P. Tetrahedron 2009, 65, 8259-8268. Cuevas, F.; Garcia-Granda, C; Buschmann, H.; Torrens, A.; Yenes, S.; Pericas, M. A. Synlett 2007, 119-122. Krafft, M. E. J. Am. Chem. Soc. 1988,110, 968-970. Krafft, M. E. Juliano, C. A.; Scott, I. L.; Wright, C; McEachin, M. D., J. Am. Chem. Soc. 1991,113, 1693-1703. Krafft, M. E.; Juliano, C. A. J. Org. Chem. 1992,57, 5106-5115. Brown, J. A.; Janecki, T.; Kerr, W. J. Synlett 2005, 2023-2026. Rivero, M. R.; De la Rosa, J. C; Carretero, J. C. J. Am. Chem. Soc. 2003,125, 14992-14993. Rivero, M. R.; Alonso, I.; Carretero, J. C. Chem. Eur. J. 2004,10, 5443-5459. Miller, K. A.; Shanahan, C. S.; Martin, S. F. Tetrahedron 2008, 64, 6884-6900. [R] Teobald, B. J. Tetrahedron 2002,55,4133^1170. Green, J. R.; Tjeng, A. A. J. Org. Chem. 2009, 74, 7411-7416. Diaz, D. D.; Betancort, J. M.; Martin, V. S. Synlett 2007, 343-359. [R] Hegedus, L. S. Transition Metals in the Synthesis of Complex Organic Molecules University Science Books: Mill Valley, CA, 1994, pp 245-246. Closser, K. D.; Quintal, M. M.; Shea, K. M. J. Org. Chem. 2009, 74, 3680-3688. Smit, W. A.; Gybin, A. S.; Shashkov, A. S.; Strychkov, Y. T.; Kyz'mina, L. G.; Mikaelian, G. S.; Caple, R.; Swanson, E. D. Tetrahedron Lett. 1986,27, 1241-1244. Rowley, E.G.; Schore, N. E. J. Org. Chem. 1992,57,6853-6861. Takano, S.; Inomata, K.; Ogasawara, K. J. Chem. Soc, Chem. Commun. 1992, 169-170. Bernardes, V.; Kann, N.; Riera, A.; Moyano, A.; Pericas, M. A.; Greene, A. E. J. Org. Chem. 1995,60,6670-6671. Jamison, T. F.; Shambayati, S.; Crowe, W. E.; Schreiber, S. L. J. Am. Chem. Soc. 1997, 119, 4353^363. Crawford, J. J.; Kerr, W. J.; McLaughlin, M.; Morrison, A. J.; Pauson, P. L.; Thurston, G. J. Tetrahedron 2006, 62, 11360-11370. Billington, D. C; Kerr, W. J.; Pauson, P. L. J. Organomet. Chem. 1987,328, 223-227. Caldwell, J. J.; Cameron, I. D.; Christie, S. D. R.; Hay, A. M.; Johnstone, C; Kerr, W. J.; Murray, A. Synthesis 2005, 3293-3296. Miller, K. A.; Shanahan, C. S.; Martin, S. F. Tetrahedron 2008, 64, 6884-6900. Honda, T.; Kaneda, K. J. Org. Chem. 2007, 72, 6541-6547. Min, S.-J.; Danishefsky, S. J. Angew. Chem., Int. Ed. 2007, 46, 2199-2202. Kaneda, K.; Honda, T. Tetrahedron 2008, 64, 11589-11593. Kozaka, T.; Miyakoshi, N.; Mukai, C. J. Org. Chem. 2007, 72, 10147-10154. Dake, G. R.; Fenster, E. E.; Patrick, B. O. J. Org. Chem. 2008, 73, 6711-6715. [R] Tafesh, A. M.; Weiguny, J. Chem. Rev. (Washington, D. C.) 1996, 96, 2035-2052. Ragaini, F. Dalton Trans. 2009, 6251-6266.

Name Reactions for Carbocyclic Ring Formations Vazquez-Romero, A.; Rodriguez, J.; Lledo, A.; Verdaguer, X.; Riera, A. Org. Lett. 2008, 10, 4509-4512. Verdaguer, X.; Lledo, A.; Lopez-Mosquera, C; Maestro, M. A.; Pericas, M. A.; Riera, A. J. Org. Chem. 2004, 69, 8053-8061. Verdaguer, X.; Moyano, A.; Pericas, M. A.; Riera, A.; Maestro, M. A.; Mahia, J. J. Am. Chem. Soc. 2000,122, 10242-10243.

Chapter 3 Five-Membered Carbocycles

3.6

181

Weiss-Cook Reaction

Paul Galatsis 3.6.1 Description The Weiss-Cook reaction1 entails the formation of cz's-bicyclo[3.3.0]octane ring systems from the condensation of 1,2-dicarbonyl compounds with 3oxoglutarate diester derivatives. Decarboxylation of the immediate reaction product affords access to the parent carbon scaffold. Me02C

H

Me02C

C02Me O^R"

Me02C

< ~ ~ < C02Me Me02C

t hR' C02Me

R" C02Me

-co2

R'

·*-

/H—s ^=0 o=< R"

Posner2 classified this three-component coupling reaction as a 3 + 2 + 3 process, based on the nature of what the reactants contribute to the final product. In addition, the Weiss-Cook reaction has been compared to the Diels-Alder reaction when one appreciates the potential of this reaction to rapidly generate a high level of molecular complexity in a single transformation.1 This reaction generates four carbon-carbon single bonds and two rings compared to two carbon-carbon single bonds and a single ring for the prototypical Diels-Alder reaction. 3.6.2 Historical Perspective The bicyclo[3.3.0]octane system had been disclosed in the literature before Weiss. The initial report was by Schroeter in 1922.3 More definite accounts of this compound were reported later by several groups.4 These approaches to the bicyclo[3.3.0]octane system suffered from multiple steps with a poor overall yield. Weiss and Edwards, in 1968, published their findings detailing a single-step preparation of this scaffold.5 Subsequently, Weiss and Cook, working jointly, have elaborated on the mechanism of this reaction and its use in organic synthesis. 3.6.3 Mechanism From a mechanistic standpoint, the process involved in the bond formation experienced in the Weiss-Cook reaction is a series of Aldol and Michael reactions.6 This reaction manifold is initiated by an Aldol reaction of oxoglutarate 2 with dicarbonyl 1. The active species facilitating this bond

Name Reactions for Carbocyclic Ring Formations

182

forming process under acidic conditions is the enol of 2. Under basic reaction conditions, the corresponding enolate of 2 is the active species. The resultant ß-hydroxy carbonyl 3 can undergo an intramolecular Aldol reaction to form the first ring of the bicyclic system found in 6. Cyclopentenone 5 is produced upon dehydration of 6. This sets up the system to add the second equivalent of oxoglutarate by a Michael addition to afford 8. A subsequent dehydration reaction generates 9 that can undergo an additional Michael C02Me

C02Me

.0

.C0 2 Me

"°M

OH C02Me 4

HOn \

//

C02Me

R" C02Me

2 Michael C02Me R. Me0 2 C. H O u ^ /

Me02C

R

"

c

°2Me

_H

0

Me02C

R'

Me02C

R

"

c

°2Me

9

Me02C

MeQ R.

/

Michael

Chapter 3 Five-Membered Carbocycles

183

reaction to form 11, which contains the expected bicyclic scaffold. While most depictions of this product in the literature are as shown in 11, the compound primarily exists in the tò-enol tautomer shown in 10.7 Ultimately, decarboxylation of 11 can result in the parent carbon framework 12. For 11/10 and 12, eis ring fusion is observed as it is the most thermodynamically stable configuration. pH6.8

C02Me 13

Key to validating this reaction sequence was confirming that cyclopentenone 5 (the 1:1 adduct of 1 and 2) was an intermediate along the pathway to 11. An initial branch point for this process was determined when compounds such as camphorquinone 13 was used as component l.6c'8 The steric hindrance associated with diketo 13 resulted in the isolation of 14. Based on this observation, it was concluded that the initial Aldol adduct 3 could tautomerize to 4, which could then undergo an intramolecular cyclization to 7. This intermediate, analogous to 14, turns out to be the end product for sterically hindered reactants. The tipping point between steric and electronic effects on the reaction outcome was determined by studying a number of diketo derivatives.6 '9'10 The product distribution between the 1:1 adduct 5 and the 1:2 adduct 11 was measured for a series of 1 (Table 1). Entries 1-4 show that simple alkyl groups or monosubstituted cyclic derivatives of 1 provide excellent yields of the bis-adduct 11. Similar results were observed for cyclic derivatives of 1 (entries 10-12). The situation changes when derivatives with greater steric requirements are subjected to this reaction (entries 5-9). The cyclopentyl derivative (entry 5) afforded 11 but in poor yield. Homologating by a single carbon to the cyclohexyl deriviative (entry 6) now resulted only in the monoadduct 5. Using the phenyl and 2-thienyl derivatives (entries 7 and 8, respectively) also resulted in the formation of 5. In sharp contrast to these latter results, the 2-furyl derivative (entry 9) afforded only 11. Thus the sterically more compact 2-furyl moiety appears to provide the appropriate balance of reactivity and steric hindrance to allow reaction with a second equivalent of 2.

184

Name Reactions for Carbocyclic Ring Formations

C0 2 Me

HO

C0 2 Me 1

2

C0 2 Me

Me0 2 C

R.

C0 2 Me

C0 2 Me

Me0 2 C

R

C0 2 Me

5

Entry 1 2 3 4 5 6 7 8 9 10 11 12

11

Table 1.

1 (R' / R") H/H Me/H Ph/H Ph/Me cyclopentyl cyclohexyl phenyl 2-thienyl 2-furyl -(CH2)3-(CH2)4-(CH2)6-

"

5 (%) 0 0 0 0 0 61 70 77 0 0 0 0

11 (% 70 52 66 68 12 0 0 0 60 45 81 80

3.6.4 Variations and Improvements Turner has described two reaction-type extremes,11 plateau-type and pointtype reactions, based on the reaction yield vs. optimum reaction conditions. While the reaction conditions first disclosed by Weiss were an improvement over the existing methods to assemble the bicyclo[3.3.0] scaffold, the overall yield was low and very sensitive to reaction conditions, i.e., a point-type reaction. To increase the synthetic utility of this chemistry, reaction conditions were investigated to transition it to a plateau-type reaction. The original preparations3'4 of the bicyclo[3.3.0]system were multistep processes and not very efficient in terms of overall yield (~ 15%). The initial publication by Weiss and Edwards,5 while comparable in yield to the previous reports, the efficiency of a multicomponent, single-step process made this variation more attractive. The initial reaction conditions focused on neutral to slightly acidic conditions,12 which allowed the intermediate tetra-ester 11 to precipitate as the major product from a mixture containing side products 15 and 16.

Chapter 3 Five-Membered Carbocycles

°
Me02C

R.

Me02C

R

Me02C

C02Me

" C02Me

185 R.

Me0 2 C

11

C02Me

~C02Me O 15

Me02C

OjvOH/C°2Me

C02Me

Me02C ΜΘ02Ο'|Η H

°

^

N

C02Me

16

The key to maximize the yield of the desired intermediate 11 was to keep the pH constant. This resulted in a shift of all the equilibria as a consequence of the precipitate formation. A dramatic improvement in yield was obtained by Bertz and Woodward,13 when it was determined that basic pH or use of the preformed enolate of 2 in refluxing methanol provided the optimal reaction conditions. A shift from the original 15%) yield to more respectable 60-70% yields could be observed and this result could be maintained even upon scale-up of the reaction. 3.6.5

Synthetic Utility

The Weiss-Cook reaction has seen great utility in the total synthesis of nonnatural as well as natural products. This has resulted from the ability of the reaction to rapidly assemble a highly functionalized, conformationally constrained carbon scaffold that provides rapid access to advanced intermediates that are readily modified for diverse target synthesis. During the 1970s and 1980s, the isolation and structure elucidation of a great variety of natural products containing multiple five-membered ring frameworks, the polyquinanes, led to an explosion in approaches to these biologically active targets. Our survey of these approaches begins with the triquinane sesquiterpene isocomene, 22. Several groups14 employed the Weiss-Cook reaction for the preparation of 22 and a compilation of the routes began with the reaction of 2 with dicarbonyl compound 17 using slightly acidic conditions of pH 6.8. Hydrolysis of the esters, decarboxylation, and esterification of the pendant acid moiety generated 18.

Name Reactions for Carbocyclic Ring Formations

186

Monoprotection of the ketone functionality was accomplished in two steps with tó-ketal formation followed by selective monodeprotection to afford 19. Wolff-Kishner deoxygenation of the free carbonyl, hydrolysis of the ketal, and intramolecular Aldol reaction gave rise to the desired scaffold 20. Introduction of the remaining methyl groups was accomplished in a stepwise fashion. The second quarternary methyl was added by methylation of the enolate of 20. Selective mono-ketal formation of the angular cyclopentanone allowed Wittig olefination of the linear cyclopentanone. Hydrolysis of the ketal also resulted in isomerisation of the exocyclic alkene to produce 21. The ketone was converted to the corresponding enone upon selenoxide elimination. Exposure to dimethyl cuprate resulted in the Michael addition of the final methyl group. The synthesis was completed by Wolff-Kishner deoxygenation to afford 22. C0 2 Me

+ Me0 2 C

O

C0 2 Me

TsOH

2. HCI, HOAc 3. KF, Mel

2. 0.3 eq TsOH 18

1. NH 2 NH 2 KOH © 2. H 3 0 3. TsOH

19

C0 2 Me1.HO-^X^OH

1. pH6.8 H 2 0, MeOH

17

1. LDA, Mel 2. BF3-OEt2 H S ^

S H

3. Ph3P= 4. TsOH

,

!

20

1. LDA, PhSeCI 2. mCPBA 3. Me2CuLi 21

4. NH 2 NH 2 K 2 C0 3

22

A synthesis of the related sesquiterpenoid pentalene, 26, also began with the Weiss-Cook reaction product 12 (R' = R" = H).15 Wittig olefination was carried out on the mono-ketal of 12 followed by hydrolysis of the ketal. The resultant ketone was reduced to the corresponding alcohol and the exocyclic alkene underwent cyclopropanation to produce 23. Oxidation of the alcohol generated a ketone that could be converted to the enone using the

Chapter 3 Five-Membered Carbocycles

187

conditions of Saegusa. The remaining carbon atoms for the angular cyclopentane ring were now introduced using a cuprate reagent generated for cyclopentane annulation. Based induce ring-closure afforded the advanced intermediate 25 that was eventually transformed into 26. 1. Ηθ"^><^ΟΗ

TsOH 2. Ph3P=

ΌΗ

3. 0.1% H2S04 4. LiAIH4 5. CH2I2, Et2Zn

H 12

CuLi

23

ci

H O

2. KH

H

H

1. PCC 2. TMSI 3. Pd(OAc)2

^ >

H

24

25

26

Modhephene, 34, was the first isolated propellane natural product. As such, the Weiss-Cook reaction was the perfect method for its construction.16 The process began with the condensation of 2 with diketone 27. Standard conditions for decarboxylation produced the core scaffold 28. Hydrogenation of the mono-enol phosphate afforded the monoketone 29. The cyclopropyl derivative 30 was prepared by copper-catalyzed decomposition of a diazoketone. gem-Dimethylation to generate 31 preceded carboxylation and esterification to afford the advanced intermediate 32. Cuprate-induced cyclopropane ring opening and methylation of the βketoester introduced the final carbon atoms giving rise to 33. Lithium iodide induced decarboxylation preceded reduction of the ketone followed by dehydration with Martin's sulfurane, thus producing 34.

27

"

+

Me02C^^Av/C02Me 2

1. LiHMDS (EtO)2POCI -*- O 2. H2, Pt/C

"O ■*- O

28

29

Name Reactions for Carbocyclic Ring Formations

188

1. LDA, TsN3

KOiBu ■*Mel

2. CuS04

1. fBuLi 2. C0 2

O

3. CH2N2 31

30 s

- \ I Me02C

% 32

/

1. Lil 2. reduction

1. Me2CuLi 2. KOfBu, Mel

pMe02C

3.

_

CF3 Ph, 0—(-Ph s' CF 3 Ph' 0

F 3 CXCF 3

The cytotoxic sesquiterpenoid quadrone, 38, has an embedded diquinane carbon framework that allowed the Piers's group to leverage the chemistry of the Weiss-Cook reaction.17 The monoketal 35 is readily available from 12 (R/ = R" = H). Several transformations converted this compound into the vinyl cyclopropane 36. Thermal rearrangement of the scaffold employing a Cope process afforded tricyclic 37. This compound was readily elaborated into 38.

Gymnomitrol, 39, is another sesquiterpenoid that encompasses an embedded diquinane scaffold. This becomes readily apparent when one examines the alternate representation for the compound. Again the use of the output from the Weiss-Cook reaction was found to be a rapid entry to this system in which two groups employed 40 as their foundation for the synthesis of 39.18 As we have seen, 40 is easily obtained from the reaction of 1 (R' = R" = Me) and 2.

Chapter 3 Five-Membered Carbocycles

OH

HO'

189

:> o

39

40

Carboprostacyclin, 43, a stable and biologically active analogue of prostacyclin (PGI2) provides an additional example of the utility of the The Weiss-Cook reaction product 41 was Weiss-Cook reaction.19 transformed into the advanced intermediate 42. A Wadsworth-HornerEmmons reaction provided a method to append the alcohol sidechain to the aldehyde moiety and a Wittig reaction, on the deprotected ketone, introduced the carboxy sidechain for the desired target 43. .C0 2 H

ΓΛ °χθ H-K-^H ^ >

H-W-H

C^>

X/^CHO O

TBSÖ 42

41 Π

o^ÌT>oOo

43 H

C02Me

C02Me

H 41

-Φ'

C02Me

46

O-Gluc

The monoterpene glucoside loganin, 46, is a key intermediate in the biosynthesis of several alkaloid families. The c/s-fused, bicyclic framework, 41, derived from the Weiss-Cook reaction was exploited for two of its attributes. One of the rings was fragmented as a precursor to the

Name Reactions for Carbocyclic Ring Formations

190

dihydropyran ring, and the topology of this scaffold was used to control stereochemistry.20 To this end, 41 was elaborated into 44, which set the stage for ring fragmentation. Ozonolysis with a reductive work-up generated 45. This compound embodied a significant amount of the structure of 46 and was easily converted into this desired compound. The final example, from the natural product category, is that of bifurcarenone 47. This compound is an inhibitor of mitotic cell division and structurally consists of an unprecedented monocyclic diterpenoid moiety in combination with a hydroquinone scaffold. Retrosynthetically, it was envisioned to arise from the coupling of the three fragments 48, 49, and 50.

OMOM

The Weiss-Cook reaction was used to generate the starting material for compound 48.21 The advanced intermediate 51 was readily obtained from the reaction of 2 with 1 (R' = R" = Me). Baeyer-Villiger reaction followed by reduction afforded lactol 52. Aldehyde 53 was prepared by ketalization of the latent aldehyde, silylation of the pendant alcohol, and hydrolysis of the ketal back to the aldehyde. The synthesis of 48 was completed by protection of the cyanohydrin of the aldehyde present in 53. 1. mCPBA 2. DIBAL

/-J/\/OH

V^o

51 1. TMSCN Znl2 2. PPTS

52

rf"Y 0EE V - k CN OTBS 48

1. Et2AICI

4r

CHO

2. TBSCI 3. HgCI2

53

OTBS

Chapter 3 Five-Membered Carbocycles

191

As we have summarized for natural product total synthesis, the Weiss-Cook reaction has enjoyed equal utility in the generation of nonnatural products. This exemplification begins with an overview of the semibullvalene system (Figure 1). The tricyclo[3.3.0.0 ' ]octane scaffold is structurally configured to undergo a facile, degenerate Cope rearrangement with a very low energy barrier. The barrier for this interconversion has been calculated to be as low as 3.6 kcal/mol for the parent system.22 Figure 1

Upon examining the structure of semibullvalene, shown in Figure 1, it becomes obvious how the Weiss-Cook reaction could be implemented in the construction of this framework. The preparation23 of the substituted semibullvalene 55 began with the Weiss-Cook diketone 11 (R' = R" = Me). Bromination followed by cyclizing dehydrobromination gave rise to 54. Reduction of the ketones and conversion to the corresponding mesylates preceded a conjugate 1,4-elimination reaction to afford the substituted derivative 55. Me02C

C02Me

Me02C

C02Me

Me02C

C02Me

Me02C

C02Me

11

54

1. Dibal 2. MsCI 3. Nal

C02Me C02Me

Me02C Me02C 55

„24

A related synthesis converted 12 (R' = R" = Me) to the cyanohydrin. This intermediate was dehydrated with phosphorous oxychloride, extensively

Name Reactions for Carbocyclic Ring Formations

192

brominated under radical reaction conditions, and finally zinc-copper couple mediated debromination to afford variant 56. 1. 2. 3. 4.

TMSCN, KCN POCI3 Br2, hv Zn-Cu

Br^

■

/r^Nj^v' \

^

II

CN CN 56

12

Triquinacene, 57, has been a great source of interest for many years due to the potential for it to dimerize to dodecahedrane 58. This compound was first synthesized by Woodward in 1964 and was the target of several groups.25 In addition, the potential for the three alkene moieties to participate in conjugation in the form of neutral homoaromaticity led to an entire workstream of several independent laboratories to confirm this phenomenon of theoretical interest.

:>

A more recent approach to 57 began with the Weiss-Cook reaction 97

product 59. Trapping the enol tautomer of this compound with diazomethane preceded alkylation with allyl iodide and hydrolysis/ decarboxylation to generate 60. The final sequence of reactions involved ozonolysis, aldol cyclization, reduction, and dehydration afforded 57. fBu02C

C02fBu

«KiH

CH2N2 KH allyl iodide ' M \ 4 HCI, HOAc fBu02C H C02fBu *■ 59 H

1

H

H 60

1. O3 HCI ^ B2Hg 4 · HMPA

H>t

\^ /

#

57

With the disclosure of this protocol for the synthesis of 57, the opportunity to rapidly generate triquinacene analogs became viable. One of

Chapter 3 Five-Membered Carbocycles

193

the major side reactions in the attempted dimerization of 57 is that the requisite concave to concave orientation could not be guaranteed. A propellane variant of 57 was prepared to improve the probability of the correct orientation for the photodimerization toward 58.28 The approach began with the Weiss-Cook reaction of 61 with 62 with diazomethane enol ether formation produced an intermediate that could intercept the chemistry from the preceeding synthesis. Allylation followed by hydrolysisdecarboxylation afforded 63. The derivatized triquinacene 64 was produced after ozonolysis, Aldol reaction, reduction, and dehydration. 1. K 2 C0 3 C0 2 fBu 2. cHoN, Ί ΙΝ 2

1. 2. =0 3. 4. //

2

3. KH ■*-04. allyl iodide 5. HCI, HOAc

o3 HCI

_

B2Hg

HMPA

/

Ì V ^

^=s/ 64

63

Using a similar strategic approach, 29 ellacene (1,10-decanotriquinacene) 65 has also been prepared. Photochemical and/or high pressure (130 kbar) failed to effect dimerization of this compound to the desired dodecahedrane derivative 66. hv

65

-X-*-

(CH 2 ) 8

8(H2C) 66

The tetrahedral nature of tetracoordinate carbon is well ingrained into practitioners of organic chemistry. However, Hoffmann has provided a theoretical analysis for stabilizing a tetracoordinate planar carbon.30 Access to these sorts of compounds was first made possible with the synthesis of stauranes. This name was coined by Cook and Weiss and is derived from the Greek stauros meaning "cross".31 The first member of this family of compounds was 72. Weiss-Cook reaction of glyoxal 67 with 2 produced 68 after hydrolysis and decarboxylation. Acid-catalyzed Aldol reaction converted 68 into the tetraketo staurane 69. Diborane reduction and dehydration by heating in HMPA afforded the desired target 72. Alternatively, diacid 68 could also be obtained from glyoxal 70.32 The Weiss-Cook reaction product 71 was elaborated into 68 by ozonolysis of the cyclopentenyl moiety followed by oxidation to the diacid.

Name Reactions for Carbocyclic Ring Formations

194

,C02Me -i. p H8.3 >0 Me02C

H

°2C

C02H NpS03H

2. HCI, HOAc

1. 0 3 2. H2, Pd/C 3. Jones

O^o l^

1. pH8.3 2 2. HCI, HOAc

=o

H 69

H 68

67

■H

»►H-

1. B2He 2. HMPA

o

70

The versatility of the Weiss-Cook reaction was leveraged in the synthesis of an isomer of 72. To this end, reaction of 73 with 2 produced 74 after hydrolysis/decarboxylation. Ozonolytic cleavage of the cyclooctene moiety resulted in the formation of bis-acetai 74 which was able to undergo an acid-catalyzed Aldol reaction to tetracycle 75. Reduction and dehydration converted 75 into the ow-angularly fused polyquinene 76. MeCX ^OMe 1. pH6 2. HCI, HOAc 73

MeO

74

,-OAc AcOH

1- B2Hg

H2S04

2. HMPA AcO 75

OMe

Chapter 3 Five-Membered Carbocycles

195

There are many more examples of the utility of the Weiss-Cook reaction in synthesis but this limited survey should provide an indication of what has been disclosed and spark new ideas for additional examples. 3.6.6

Experimental

While the primary literature provides multiple examples of how the WeissCook reaction can be conducted, general reaction conditions that are able to cover a diverse set of glyoxals has been report with yield ranging from 12 to 94%.34 c/s-l,5-Dimethylbicyclo[3.3.0]octane-3,7-dione C02Me

+

X 1

r°

C02Me

2

Ä

Me02C

C02Me

° ^ ° *■

Me02C

C02Me

11

0<

τ>° 12

To a solution of NaHCCh (5.6 g) in 400 mL of water (final pH 8.3) was added dimethyl 1,3-acetonedicarboxylate 2 (70 g, 0.40 mol). Biacetyl 1 (R' = R" = Me) (17.2 g, 0.20 mol) was added to the rapidly stirred solution. Over the course of 24 h, a white solid precipitated and was collected by suction filtration. Additional material could be isolated by processing the filtrate. Recrystallization from methanol afforded 58-60 g (73-75%) of tetraester 11 (R' = R" = Me). Tetraester 11 (R' = R" = Me, 24 g, 0.060 mol) was refluxed in 200 mL 1 M hydrochloric acid and 40 mL glacial acetic acid for 3-6 h. The reaction mixture was cooled in an ice bath and the solid precipitate collected by suction filtration. Recrystallization from ethanol afforded 7.5-7.7 g (7577%) diketone 12 (R' = R" = Me). 3.6.7

References

1.

[R] (a) Mitschka, R.; Oehldrich, J; Takahashi, K.; Cook, J. M; Weiss, U.; Silverton, J. V. Tetrahedron 1981, 37, 4521. (b) Org. Synth. Highlights 1991, 121, 121. (c) Gupta, A. K.; Fu, X.; Snyder, J. P.; Cook, J. M. Tetrahedron 1991, 47, 3665. (d) Fu, X.; Cook, J. M. Aldrichimica Acta 1992, 25, 43. [R] Posner, G. H. Chem. Rev. 1986, 86, 831. Schroeter, G. Ann. 1922, 426, 1. (a) Paul, H. Chem. Techn. 1956, 8, 189. (b) Tanaka, S. J. Am. Chem. Soc. 1958, 80, 5264. (c) Yates, P.; Hand, E. S.; French, G. B. J. Am. Chem. Soc. 1960, 82, 6347. Weiss, U.; Edwards, J. M. Tetrahedron Lett. 1968,4885.

2. 3. 4. 5.

196 6.

7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18. 19. 20. 21. 22. 23. 24. 25. 26. 27. 28. 29. 30. 31. 32. 33. 34.

Name Reactions for Carbocyclic Ring Formations (a) Edwards, J. M.; Qureshi, I. H.; Weiss, U.; Akiyama, T.; Silverton, J. V. J Org. Chem. 1973, 38, 2919. (b) Yang, S.; Cook, J. M. J. Org. Chem. 1976, 41, 1903. (c) Yang-Lan, S. Mueller-Johnson, M.; Oehldrich, J.; Wichman, D.; Cook, J. M. J. Org. Chem. 1976, 41, 4053. (d) Bertz, S. H.; Adams, W. O.; Silverton, J. V. J. Org. Chem. 1981, 46, 2830. (e) Kubiak, G.; Cook, J. M.; Weis, U. J. Org. Chem. 1984, 49, 561. (f) Quast, H.; Roschert, H.; Peters, E-M.; Peters, K.; Schnering, H. G. Chem. Ber. 1989, 122, 523. (g) Deslongchamps, G.; Mink, D.; Boyle, P.D.; Singh, N. Can. J. Chem. 1994, 72, 1162. h) Van Ornum, S. G. Li, J.; Kubiak, G. G.; Cook, J. M. J. Chem. Soc, Perkin Trans. 11997, 3471. Camps, P. Tetrahedron Lett. 1974, 4067. Campos, O.; Cook, J. M. J. Heterocyclic Chem. 1977, 14, 711. Avasthi, K.; Desphande, M. N.; Han, W-C; Cook, J. M.; Weiss, U. Tetrahedron Lett. 1981, 22, 3475. Kubiak, G.; Cook, J. M.; Weiss, U. Tetrahedron Lett. 1985, 26, 2163. Brewster, D.; Myers, M.; Ormerod, J.; Otter, J.; Smith, A. C. B.; Spinner, M. E.; Turner, S. J. Chem. Soc., Perkin Trans. 11973, 2796. (a) Rice, K. C; Sharpless, N. E.; Weiss, U.; Highet, R. J. Tetrahedron Lett. 1975, 3763. (b) Rice, K. C; Weiss, U. Akiyama, T.; Highet, R. J.; Lee, T.; Silverton, J. V. Tetrahedron Lett. 1975, 3767. (a) Bertz, S. H.; Adams, W. O.; Silverton, J. V. J. Org. Chem. 1981, 46, 2830. (b) Bertz, S. H.; Rihs, G.; Woodward, R. B. Tetrahedron 1982, 38, 63. (c) Bertz, S. H. J. Org. Chem. 1985, 50, 3585. (a) Oehldrich, J.; Cook, J. M.; Weiss, U. Tetrahedron Lett. 1976, 4549. (b) Dauben, W. G.; Walker, D. M. J. Org. Chem. 1981, 46, 1103. (c) Paquette, L. A.; Han, Y.-K. J. Am. Chem. Soc. 1981,103, 1835. a) Piers, E.; Karunaratne, V. J. Chem. Soc, Chem. Commun. 1984, 959. b) Piers, E.; Karunaratne, V. Can. J. Chem. 1989, 67, 160. Wrobel, J.; Takahashi, K.; Honkan, V.; Lannoye, G.; Cook, J. M.; Bertz, S. H. J. Org. Chem. 1983,45,141. Piers, E.; Moss, N. Tetrahedron Lett. 1985,26, 2735. (a) Coates, R. M.; Shah, S. K.; Mason, R. W. J. Am. Chem. Soc 1979, 101, 6765. (b) Han, Y-K.; Paquette, L. A. J. Org. Chem. 1979, 44, 3731. (c) Paquette, L. A.; Han, Y-K. J. Am. Chem. Soc. 1981,103, 1831. Nicolaou, K. C; Sipio, W. J.; Magolda, R. L.; Seitz, S.; Barnette, W. E. J. Chem. Soc, Chem. Commun. 1978, 1067. Caille, J. C; Bellamy, F.; Guilard, R. Tetrahedron Lett. 1984, 25, 2345. Mori, K.; Uno, T. Tetrahedron 1989, 45, 1945. (a) Dewar, M. J. S.; Lo, D. H. J. Am. Chem. Soc. 1971, 93, 7201. (b) Cheng, A. K.; Anet, F. A. L.; Mioduski, J.; Meinwald, J. J. Am. Chem. Soc. 1974, 96, 2887. Miller, L. S.; Grohmann, K.; Dannenberg, J. J.; Todaro, L. J. Am. Chem. Soc. 1981, 103, 6249. (a) Quast, H.; Christ, J.; Gorlach, Y.; von der Saal, W. Tetrahedron Lett. 1982, 23, 3653. (b) Quast, H.; Gorlach, Y.; Meichsner, G. Tetrahedron Lett. 1982, 23, 4677. Woodward, R. B.; Fukunaga, T.; Kelly, R. C. J. Am. Chem. Soc. 1964, 86, 3162. Williams, R. V. Chem. Rev. 2001, 101, 1185. Bertz, S. H.; Lannoye, G.; Cook, J. M. Tetrahedron Lett. 1985, 26,4695. Gupta, A. K.; Cook, J. M.; Weiss, U. Tetrahedron Lett. 1988, 29, 2535. Fu, X.; Cook, J. M. J. Org. Chem. 1992, 57, 5121. (a) Hoffmann, R.; Alder, R. W.; Wilcox, C. F., Jr. J. Am. Chem. Soc. 1970, 92, 4992. (b) [R] Hoffmann, R. Pure Appi. Chem. 1911,28, 181. Mitschka, R.; Cook, J. M.; Weiss, V.J. Am. Chem. Soc. 1978, 700, 3973. Deshpande, M. N.; Jawdosiuk, M.; Kubiak, G.; Venkatachalam, M.; Weiss, U.; Cook, J. M. J. Am. Chem. Soc. 1985, 707, 4786. Venkatachalam, M.; Jawdosiuk, M.; Deshpande, M. N.; Cook, J. M. Tetrahedron Lett. 1985, 26, 2275. Bertz, S. H.; Cook, J. M.; Gawish, A.; Weiss, U. Org. Syn. 1986, 64, 27.

Name Reactions for CarbocycUc Ring Formations Edited by Jie Jack Li Copynght © 2010 John Wiley & Sons, Inc.

Chapter 4 Six-Membered Carbocycles

197

4.1 4.2 4.3 4.4 4.5 4.6 4.7 4.8 4.9 4.10 4.11 4.12 4.13 4.14 4.15

198 209 222 236 251 267 275 309 324 336 342 356 369 386 409

Bardhan-Sengupta Pheantherene Synthesis Bergman Cyclization Bogert-Cook Reaction Bradsher Cycloaddition and Bradsher Reaction Bradsher Reaction Darzens Synthesis of Tetralin Derivatives Diels-Alder Reaction Dötz Benzannulation Elbs Reaction Fujimoto-Belleau Reaction Haworth Reaction Moore Cyclization Myers-Saito Cyclization Robinson Annulation Scholl Reaction

198

4.1

Name Reactions for Carbocyclic Ring Formations

Bardhan-Sengupta Phenanthrene Synthesis

Timothy T. Curran 4.1.1 Description The Bardhan-Sengupta phenanthrene synthesis is a two-step process. The first step is reaction of a hydroxy-substituted phenyl alkane 1 or phenylsubstituted alkene 2 with a phosphorus-containing acid or dehydrating agent, i.e., H3PO4, P2O5 or polyphosphoric acid (PPA) to generate a carbocationic species, which then undergoes electrophilic aromatic substitution (EAS) and proton elimination to provide the corresponding octahydrophenanthrene 4. Subsequent dehydrogenation of 4 then provides the phenanthrene ring system 5.

G G

HO 1 or

[i

G

Θ

protic or Lewis /\ acid

EAS

+-

3

rrXS \ i ^

2

G

· ΎΊ

(

G

χ

4

Se, heat |

I p T"

^

or dehydrogen agent 5

In addition, due to the cationic nature of the cyclization step, there can be an array of byproducts generated depending on the stability of the cation and neighboring groups (which are part of the cyclizing substrate), which may affect the cyclization product. The dehydrogenation was initially done with elemental selenium and heat (~ 300 °C). More mild conditions using a variety of metals have been developed since the initial inception.

Chapter 4 Six-Membered Carbocycles

4.1.2

199

Historical Perspective

In 1932, Bardhan and Sengupta1 reported the use of P2O5 to cyclize hydroxy ester 6 that, upon treatment of the crude product with Se metal and heat (300-320 °C), provided 8 presumably through an intermediate like compound 7 (R = H or Et). In an additional publication, the authors provided more experimental detail and examples on the formation of substituted phenanthrenes.

C0 2 Et OH

P205, * heat

Me 6

Initial controversy arose when it was suggested that the Se dehydrogenation step provided methyl scrambling (migration) of alkyl groups on the aromatic ring. This notion was put to rest by experimentation in other groups.3 Like the Bogert-Cook reaction (see Section 4.3), for the cyclization step, the Bardhan-Sengupta cyclization conditions also reportedly formed spirane products. Electron-donating groups (EDG) on the aromatic ring were reported to increase the formation of the spirane.4 Barnes suggested that intermediates formed during the cyclization containing a neighboring carboxylate group, mitigated spirane formation due to formation of dication 10.5 7 Also, for these substrates in which dication formation was suggested, electron-rich aromatics were required for the cyclization to proceed in good yield. .OH

HO^OEt 9

©

HO^OEt 10

HO^OEt 11

Much like the work conducted by the Bogert and Cook groups, the Bardhan-Sengupta synthesis of phenanthrenes helped lead to the determination of the carbon framework for steroids and was used to prepare terpene-type natural products.

Name Reactions for Carbocyclic Ring Formations

200

4.1.3

Mechanism

The proposed mechanism of the Bardhan-Sengupta cyclization is similar to that reported for the cyclization by Bogert and Cook.3'7 Although, there are instances in which the phosphorous containing acid or dehydrating agent appears to be more mild or selective than reported for the H2SO4 promoted cyclizations (vida infra), the conformational and nonbonding steric interactions governing the cyclization under acid-promoted conditions remain. Activation of the alcohol for leaving via protonation or phosphorylation8 and subsequent leaving would generate carbocation 14. The carbocation can suffer alkene formation delivering 15, hydrogen or alkyl 1,2-shift (not shown), or electrophilic aromatic substitution providing the desired cyclized product 16. It is important to remember that 15 can be protonated by phosphoric acid, getting one back to a carbocationic species, which can subsequently undergo productive cyclization. Aromatization then provides the octahydrophenanthrene 17. The subsequent dehydrogenation, which historically employed Se metal and heat, has not been well studied or characterized. The supporting data suggest that dehydrogenation takes place by first complexation of Se-Se with an allyl type system, followed by attachment to the allylic or benzylic carbon atom providing 18. This bond-forming step could take place by radical formation on Se, subsequent formation of a benzyl radical, followed by addition of the radical to Se2. At the elevated temperature, the authors propose a radical mechanism breaking the Se-Se bond in compound 18, generating HSe· radical and the alkyl-selenyl radical 19. Both 19 and HSe· can then propagate the radical sequence and generate benzyl radical like 20 and alkylselenol 21. Elimination of H2Se provides alkene 22. A continued combination of electrophilic Se addition/elimination and radical dehydrogenation/substitution-elimination sequences may then take place resulting in fully aromatized material 23. The amount of t^Se released is not stoichiometric with the dehyrogenations that occur or with the amount of Se spent; therefore, there are multiple reaction pathways leading to ring unsaturation. The mechanism is likely not to be reinvestigated due to the toxicity of Se metal and the development of alternative dehydrogenating conditions, which occur at lower temperature and are less destructive to thermally-sensitive materials.

f^j K^

12

0H

P2Q5, H3PO4

J^J \ ^

13

OX V

X = H 2 or P 2 0 5 H

Chapter 4 Six-Membered Carbocycles

201

disproportionation -

^ HSe*

several iterations

As with the Bogert-Cook cyclization, there have been three possible intermediates proposed as the active ring-forming intermediate in the Bardhan-Sengupta cyclization.4'7 Specifically, the activated hydroxyl group 24, the carbocation 25 (which, depending on the substitution, could be a mixture of carbocations with 26 potentially leading to the spirocyclic compound), and the bridged intermediate 27.

24 25 P = H or an activating phosphoric intermediate

26

202

Name Reactions for Carbocyclic Ring Formations

Spirane formation was observed when electron-donating groups (EDG) were attached to the aromatic ring and the carbocation formed at the carbon bearing the phenethyl group. For example, cyclizaton of 28 provided 29 in lower yield than 30 was converted to 29 due to the formation of the spirane.4 85% H3PO4

MeO

85% H3PO4

Me

OMe

MeO

P2O5

OMe

81% 29

30

Having EDGs can also work to one's advantage as they provide a reactive aromatic ring poised to attack and not allow carbocation migration as evidenced by the high yield obtained for the conversion of 31 into 32. 85% H3PO4 OMe

*-

P2O5

MeO OMe

95%

Electronic effects of the ring have been observed in that electronwithdrawing groups (EWG) do slow the rate of cyclization when attached to the nucleophilic aromatic ring. This was nicely demonstrated in a study by Vingiello and Newallis on substrate 33.10 While cyclization of 33a and the chlorosubstituted 33b gave comparable yields, once the nucleophilic aromatic ring contained a chlorine (33c,d), the yield was cut in half under similar conditions. Substitution

yield

34a, X == Y = H

60%

34b, X, = CI Y == H 54% 34c, X = H; Y = CI

26%

34d,X = Y = CI

27%

Chapter 4 Six-Membered Carbocycles

203

4.1.4 Variation and Improvements Cyclization of Keto-Substrates In addition to the use of hydroxyl or alkenyl substrates, keto substrates have also been cyclized. Polyphosphoric acid (PPA) was used to promote the cyclization of dione 35 into tetracyclic ketone 36 in > 90% yield.11

Alternative Dehydrogenating Agents Several heavy metal-mediated dehydrogenation reactions have been developed in addition to the use of selenium. Pt, Pd, Ni, Ni-Cr, Rh, as and S have all been studied for dehydrogenation of substrates resulting from cyclization.12 Dehydrogenation of tetrahydrophenanthrene 37 provided phenanthrene 38 in 83% yield using palladium on carbon.13

The addition of substrates to enable the transfer of hydrogen, rather than merely allowing the H2 to be expelled, has improved the safety of dehydrogenation reactions. Additives for such reactions are merely alkenes (cyclohexene, maleic acid, or benzene). While mechanistically use of elemental S in place of Se is proposed to be similar, the dehydrogenation reaction using heavy metals is considered to be merely the reverse of the hydrogenation reaction. A proposal of how the substrate binds to the surface of the catalyst to promote the process has been proposed.14 Use of quinones like chloranil and DDQ has also been employed for this dehydrogenation. Halogenation-elimination with bromine or NBS has been a chemical means to promote the dehydrogenation. However, with the bromination/elimination protocol, one must be careful as aromatic halogenation can occur.12

Name Reactions for Carbocyclic Ring Formations

204

see Table

39

Conditions

Yield

Pd/C, reflux 22 h

quant

DDQ, PhH, reflux

quant

NBS, CCI 4 ,

74%

General Selectivity for the Cyclization In comparison to conditions used for the cyclization of alcohols or alkenes described, use of phosphorous pentoxide (P2O5), phosphoric acid (H3PO4), or a mixture of the two was shown to enable cyclizations, which did not proceed using classical Bogert-Cook conditions. Notably, the cyclization of primary alcohols like compound 41 failed to provide cyclized material 39 using H2SO4 while use of H3PO4 provided a 61% yield of 39.15 85% H3PO4

61% 39

On the other hand, cyclization of primary alcohol 42, bearing juxtaposed groups for cation stabilization (Me, H), gave predominantly products resulting from rearrangement.

Me 45

Me

The reaction was also determined to be primarily c/s-selective. Mossettig and van deKamp reported the cyclization of 46 provided a 70:20 mixture of eis and trans isomers 47 and 48 using P2O5. .OH

46

P?0 2 ^ 5:

H 48, 20%

Chapter 4 Six-Membered Carbocycles

205

Another example in which the phosphoric reaction conditions have proven more selective than other conditions was shown in the conversion of enone 49 into only the c/s-fused tricyclic compound 50. Use of other reagents reported, provided a mixture of eis and trans isomers. Note that this substrate also generates a tetrasubstitued carbon, not necessarily a facile bond to make in excellent yield.17 PPA

» 120°C 96%

Different Disconnection of the Phenantharene Synthesis A recent change in the disconnection of putting together the phenanthrene ring system has appeared using conditions similar to the Bardhan-Sengupta method.18 PPA promoted Freidel-Crafts type acylation followed by electrophilic cationic cyclization of of 51 and 52 gave 53. Aromatization of 53 with Pd/C then provided the phenanthrenes 54 in overall modest yield. In this work, the authors did not rigorously assign the stereochemistry of the cyclization but suggested that a 1:1 mixture to predominantly the eis isomer resulted depending on substitution pattern of the starting material.

^r^co2H + 51

300 °C 72-78% 54 R,

Name Reactions for Carbocyclic Ring Formations

206

4.1.5 Synthetic Utility General Utility The cyclization has been used as a key step in Topliss' synthesis of the natural product Ferruginol 57.19 P2O5 was used to successfully promote the cyclization of alcohol 55 into the octahydrophenanthrene 56 in about 47% yield. OMe MeO

OH

Me

p?a 2^5. 130-150°C 47% Me Me

55

56

Me Me

57, ferruginol

Use of a P2O5 to promote cyclization of steroidal backbones was also accomplished by Ireland and co-workers.11 In this case, the trans product 59 proved to dominate the product mixture. The preference was suggested to be due to a combination of A-strain and torsional strain-nonbonding interactions during the cyclization. The stereochemistry of the starting alcohol 58 had no impact on the ratio of the products.

3:1 crude GC analysis

MeO

MeO

MeO

59, 64%

Conditions initially used for the Bardhan-Sengupta cyclization have been applied to a double or cascade cyclization reaction. Thus cyclization of 61 using PPA gave the c/s-fused ring system 62.7

Chapter 4 Six-Membered Carbocycles

207

OMe PPA 100 °C . H Me Me

4.1.6

62

Experimental

Polyphosphoric acid-promoted preparation of 10(9//)-l,2,3,4,4a,10act hexahydro-la,4aa-dimethylphenanthrone (50)16

o

A sample of unsaturated ketone 49 (1.046 g) was heated wth PPA (8 g) at 120 °C for 10 min. The cooled reaction mixture was diluted with water and extracted with ether. The organic layer was washed successively with saline and 10% NaHCC>3 solution. The ether solution was dried (MgS04) then evaporated to dryness to give 50 1.02 g, 96%. TLC showed one component. The solid was recrystallized from pentane, m.p. 64-65 °C. Dehydrogenation of 3-methyl octahydrophenanthrene (4)20 10%Pd/C 245 °C, 8 h 50%

3-Methyl octahydrophenanthrene 63 (20 g, 0.1 mmol, 88:12 mix of 63 and the corresponding spirane) was dehydrogenated with 10% Pd/C (1 g, 5 mol %) at 245 °C for 8 h. The reaction was cooled (solidified), dissolved in PhH, and filtered through dicalite. The filtrate was concentrated in vacuo to provide 19.5 g of a dark product. The product was dissolved in MeOH (200 mL) and was added to a solution of 30 g picric acid in MeOH (200 mL). The

208

N a m e Reactions for Carbocyclic Ring Formations

resulting picrate solid was collected and recrystallized from hot MeOH to give 19 g of yellow needles. The picrate was decomposed on a column of basic alumina using hexane to give 9 g 3-methyl phenanthrrene (64) m.p. 6 1 62 °C, 50% yield. 4.1.7 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18. 19. 20.

References Bardhan, J. C ; Sengupta, S. C. J. Chem. Soc. 1932, 2798-2800. Bardhan, J. C ; Sengupta, S. C. J. Chem. Soc. 1932, 2520-2526. Akin, R. B; Stamatoff, G. S.; Bogert, M. T. J. Am. Chem. Soc. 1937, 59, 1268-1272. Barnes, R. A. J. Am. Chem. Soc. 1953, 75, 3004-3008. Papa, D.; Perlman, D.; Bogert, M. T. J. Am. Chem. Soc. 1938, 60, 319-321. Barnes, R. A.; Hirschler, H. P.; Bluestiein, B. R. J. Am. Chem. Soc. 1952, 74, 32-34. [R] Barclay, L. R. C. In Friedel-Crafts and Related Reactions, Vol. 2, part II, Olah, G. A. Ed., Wiley, New York, NY, 1964, pp 785-977. So, Y.-H., Heeschen, J. P. J. Org. Chem. 1997, 62, 3552-3561. (a) Fitzpatrick, J. D.; Orchin, M. J. Am Chem. Soc. 1957, 79, 4765-4771. (b) House, W. T.; Orchin, M. J. Am Chem. Soc. 1960, 82, 639-642. (c) Silverwood, H. A.; Orchin, M. J. Org. Chem. 1962, 27, 3401-3404. Vingiello, F. A.; Newallis, P. E. J. Org. Chem. 1960, 25, 905-907. Ireland, R. E; Baldwin, S. W.; Welch, S. C. J. Am. Chem. Soc. 1972, 94, 2056-2066. [R] Fu, P. P.; Harvey, R. G. Chemical Rev. 1978, 78, 317-361. Bachmann, W. E.; Cronyn, M. W.; Struve, W. S. J. Org. Chem. 1947, 596-605. Tsai, M.-C; Friend, C M . ; Muetterties, E. L. J. Am. Chem. Soc. 1982,104, 2539-2543. Khalaf, A. A.; Roberts, R. M. J. Org. Chem. 1969, 34, 3571-3574. van de Kamp, J.; Mosettig, E. J. Am. Chem. Soc. 1936, 58, 1062-1063. Schmidt, C ; Thazhuthaveetil, J. Can. J. Chem. 1973, 51, 3620-3625. Ramana, M. M. V.; Potnis, P. V. Synthesis 1996, 1090-1092. King, F. E.; King, T. J.; Topliss, J. G. J. Chem Soc. 1957, 573-577. Bansal, R. C ; Samad, S. A.; Thomson, J. S.; Eisenbran, E. J. Org. Prep. Proc. Int. 1988, 20, 305-311.

Chapter 4 Six-Membered Carbocycles

4.2

209

B e r g m a n Cyclization

Nessan J. Kerrigan 4.2.1

Description

R\ ^

Δ orhv

R

\ / ^ '

R3'

f

2H* ^R 4

Κ

χ

^ "

R3 ^ ^

Κ

R

2

The Bergman cyclization, also known as the Bergman cycloaromatization, is a thermal, photochemical, or metal-mediated cycloaromatization of enediynes 1 that provides access to substituted arenes 3. 1 ' 5 The cyclization initially forms a 1,4-benzenediyl diradicai 2 which, being highly reactive, reacts with a hydrogen donor, such as 1,4-cyclohexadiene, to give an arene 3. 4.2.2

Historical Perspective

Robert George Bergman (born in 1942) discovered this reaction in 1971 while he was an associate professor at the California Institute of Technology at Pasadena. ' He later accepted an appointment as professor of chemistry at the University of California, Berkeley. Studies involving the Bergman cyclization were rare until relatively recently due to its limited substrate scope and the availability of alternative methods for construction of substituted arenes.4 However, since the discovery of naturally occurring enediynes with antitumor activity, interest in the Bergman cyclization has increased greatly, particularly with respect to its role in their mode of action.4 4.2.3

Mechanism

Bergman proposed that the reaction mechanism of the cyclization under thermal conditions (200 °C) involved the initial generation of a 1,4benzenediyl diradicai species known as para-benzyne (2). ' Bergman reported that when the reaction was carried out in a hydrocarbon solvent, such as 2,6,10,14-tetramethylpentadecane, benzene was formed as the final product.1 This suggests that the hydrocarbon solvent (RH) acts as a hydrogen atom donor to quench the diradicai intermediate 2. This result hints at the radical nature of the mechanism operative in the Bergman cyclization.

210

Name Reactions for Carbocyclic Ring Formations

+

R

Further support for this mechanism came from the results of studies in other solvents. Carrying out the cyclization in toluene led to the formation of diphenylmethane 4 as the major product, while in carbon tetrachloride, the formation of 1,4-dichlorobenzene 5 was observed. In methanol, benzene and some benzyl alcohol 6 were formed but, notably, no anisole was detected. These results could only be explained by the intermediacy of a free radical species 2a and clearly ruled out the possibility of a charged (polar) intermediate.1'2

CH,

4

Furthermore, deuterium labeling experiments under gas-phase pyrolysis conditions (200-300 °C) showed that complete scrambling of

Chapter 4 Six-Membered Carbocycles

211

deuterium between the acetylenic and the vinyl positions of lb occurred (to give lc). This demonstrated that lb is in equilibrium with lc and confirmed that lb is being converted via an intermediate (2b), in which C-l, C-3, C-4, and C-6 are chemically equivalent. Δ

1b

2b

1c

Bergman also investigated the spin state of the diradicai species 2 produced during the thermolysis of enediynes.3 On the basis of chemically induced dynamic nuclear polarization (CIDNP) studies, and trapping experiments, which used the spin correlation effect (SCE), it was deduced that most products (including substituted arenes 3) formed from 2 arise from the singlet state of the diradicai species.3 4.2.4 Variations and Improvements While the Bergman cyclization generally requires elevated temperatures (> 200 °C) for acyclic enediynes due to their high activation barriers, cyclic enediynes in contrast have lower activation energies and can cyclize at significantly lower temperatures. The difference in reactivity has been ascribed to the shortness of the distance (the cd distance) between acetylenic groups in cyclic enediynes (3.20-3.31 À for modest half-life at room temperature) in contrast to the longer distance found in acyclic enediynes {cd distance > 3.31 À). This theory was supported by agreement of molecular mechanics calculations (Macromodel, MM2) concerning cd distance with experimental observations for a variety of enediynes. To illustrate this point, 10-membered enediyne 7 underwent cyclization efficiently under moderate conditions (70 °C) to give 8.8 1,4-cyclohexadiene benzene, 70 °C 4 h, 52%

Name Reactions for Carbocyclic Ring Formations

212

The development of photochemical variants of the Bergman cychzation would contribute to the broadening of its scope and utility. However there are relatively few examples of photoinduced cyclizations, despite the promise that such an approach would have in the photodynamic therapy of cancer.9-14 Funk and co-workers reported that certain cyclic orthodialkynylarenes, such as 9, underwent the photo-Bergman cychzation on irradiation in Pyrex.10 In 2000 Russell and co-workers showed that 10membered cyclic pyrimidine enediynes could undergo cychzation efficiently (82-83%) when exposed to light (310 nm) in /-PrOH for 2-24 hours.13

Turro and co-workers showed that simple acyclic aromatic enediynes, such as 11, could also undergo Bergman cychzation under photochemical conditions. They proposed that the photo-Bergman cychzation of these substrates involved a diradicai intermediate 2 identical to that of the thermal reaction."

11

l

\^

12

Hirama and co-workers demonstrated that the photo-Bergman cychzation could be extended to both cyclic and acyclic aliphatic enediynes.12 1,2-Dipropynylcyclopentene 13 in hexane was converted to indane derivative 14 in 71% yield when irradiated with a low-pressure mercury lamp at room temperature.

Chapter 4 Six-Membered Carbocycles

hv (254 nm)

TBSO

hexane, rt 71%

CH3

213

TBSO

13

14

Hirama's group also obtained results to support the intermediacy of a diradicai species in the photo-Bergman cyclization. When cyclodeca-1,5diyn-3-ene 15 in Dg-z'-PrOH was exposed to photolysis with a low-pressure mercury lamp for 5 min, a significant amount of enediyne 18 (53% based on recovered 15) was obtained in addition to the expected cyclization product 17 (30% based on recovered 15). They suggested that 18 must be formed through retro-Bergman reaction of postulated diradicai intermediate 16, and hence provided evidence for 16 acting as an intermediate in the photoBergman cyclization.

19

hv (254 nm) 1

D8-/-PrOH rt

16

15

17 (30%)

18 (53%)

A conceptually different approach for Bergman cyclization of acyclic enediynes (and stable cyclic enediynes) relies on the use of metal ion 1 S—99

chelation to allow the reaction to proceed at lower temperatures. Metal ion chelation requires that the enediyne contain heteroatoms at appropriate positions within the enediyne scaffold. Buchwald et al. reported an elegant use of this approach for the cyclization of a bisphosphane-l,2-diaryl diyne 19.17 In this case, Pd was found to be the optimal ion and allowed the Bergman cyclization to proceed at 61 °C, instead of 243 °C in the absence of a metal ion. The change in reactivity of the enediyne 19 under metal ion chelation conditions was attributed to both conformational and electronic effects. PPh2

PPh2

19

Pd|2+

PPh,

61 °C

PPh, 20

214

Name Reactions for Carbocyclic Ring Formations

König and co-workers also made a significant contribution to this area when they showed that a bipyridyl enediyne 21 could undergo Bergman cyclization at 145 °C in the presence of Hg(OCOCF3)2.18 In the absence of the metal salt, a temperature of 237 °C was required to enable cyclization to occur. It was inferred from this result that metal ion coordination brought about a conformational change, facilitating a drop in the cyclization temperature by about 100 °C. Similar observations were made by other groups who carried out studies with amino, sulfonamido, and aldimino enediynes.19-22

Bergman cyclization at 145 °C

Hg(OCOCF3)2 Hg F3COCO

X

OCOCF3

A major advance in metal-promoted Bergman cyclizations came about when O'Connor and co-workers revealed that a ruthenium(II) complex 24 could be used to accelerate cyclizations.23 A major advantage of this approach was that there was no requisite for heteroatoms to be present within the enediyne framework, in contrast to previously reported metal ion chelation approaches. But, rather it was determined that the ruthenium(II) complex activated enediynes to Bergman cyclization through metal-alkyne interactions. In their initial report on the Bergman cyclization, O'Connor and co-workers showed that cyclic enediynes 22 and 23 underwent cyclization in the presence of ruthenium complex 24 under very mild conditions (23 °C in THF) to afford ruthenium complexed products 25 and 26 in good yields of 63% and 71%, respectively. The results of a deuterium labeling experiment implicated 1,4-diradicals as intermediates in the ruthenium-catalyzed 23 Bergman cyclization just as in prototypical thermal Bergman cyclizations

Chapter 4 Six-Membered Carbocycles

215

Cp*Ru +

R2'

RuCp* 24 THF 23 °C

22 R1 = f-Bu, R2 = H 23 R1 = R2 = Me f

25 R1 = f-Bu, R2 = H 26 R1 = R2 = Me RuCp* 24 : M. Ru MeCN' MeCN

OTf

+

NCMe

O'Connor's group later reported that 24 could be used to mediate the cycloaromatization of acyclic enediynes 27 and 28 in good yields as well.24 Deuterium-labeling experiments supported the intermediacy of a p-benzyne rather than a vinylidene intermediate.24 Cp*Ru^" \

24

R^

(1

THF 23 °C

27 R1 = R2 = Me 28 R1 = Me, R2 = TMS

29 R1 = R2 = Me, 64% 30 R1 = Me, R2 = TMS, 77%

More recently, O'Connor and co-workers have reported the first catalytic Bergman cyclization using an iron(II) complex 32 (0.3 equiv) to catalyze cycloaromatization of acyclic enediynes.25 Mild catalytic activity (3 turnovers) was achievable when photolysis was combined with iron catalysis, enabling decomplexation of the arene product from the iron complex to occur.25 n-Pr

n-Pr 31

+

FeCp* 32 γ-terpinene acetone-c/6 hv 23 °C, 9 1 %

n-Pr n-Pr

+

FeCp* 32 =

OTf

MeCN .-Fe;

Y

MeCN

NCMe

33

Related to the Bergman cyclization is the cyclization of an eneyne aliene system 34 to provide access to an aromatic system 36. This variant on

216

Name Reactions for Carbocyclic Ring Formations

the Bergman cyclization is known as the Myers-Saito cyclization.26-29 Like the Bergman cyclization, it involves a diradicai intermediate although in this case the intermediate is a σ,π-diradical 35. ' The enhanced stability of the σ,π-diradical intermediate 35 (and hence the transition state leading to it) over the 1,4-benzenediyl diradicai species 2 involved in the Bergman cyclization ensured that the reaction proceeded under much milder conditions (typically 37-100 °C) than are usually required for Bergman cyclizations.27 Mild thermolysis of 34 in 1,4-cyclohexadiene afforded 36 in 60% yield. It is interesting that methyl substitution at the aliene terminus of 34 caused acceleration of the cyclization (approximately six times faster than 34) and this was presumably due to formation of a more stable diradicai intermediate.27

34

35

36

Organometallic reagents may also be employed to facilitate the Myers-Saito cyclization. As the Myers-Saito cyclization proceeds at lower temperatures compared to the Bergman cyclization, strategies have focused on the rearrangement of an enediyne to a more reactive vinylidene eneyne before cyclization. Finn and co-workers reported the preparation of a vinylidene complex 38 through reaction of a benzodiyne 37 with CpRu(PMe3)2Cl and NH4PF6.30 They found that vinylidene complex 38 underwent cyclization at a temperature of 100 °C, in contrast to the precursor benzodiyne 37, which required thermolysis at 190 °C for cyclization to occur.30 This example clearly demonstrated the superior ability of vinylidene complexes to undergo cyclization in comparison with structurally related enediynes. C02Me

CpRu(PMe3)2CI NH4PF6 CH3OH, 25 °C

*-

Chapter 4 Six-Membered Carbocycles C0 2 Me ^

,

+

PF

217

C0 2 Me

6

Me3P S T " CH 3 CN, 100 °C 4 h, 50-70%

39

Shortly after Finn's work came to light a catalytic rhodium(I) system was reported.31 An acyclic enediyne 40 was heated to 50 °C in the presence of just 0.05 equiv of RhCl(z'-Pr2P)2 and Et3N in benzene to provide substituted arene 41 in 58% yield. The latter reaction is presumed to involve Myers-Saito cyclization of an in situ formed vinylidene complex.4'31 A catalytic cycle becomes possible due to steps involving /^-hydride elimination and reductive elimination.31 -CeH-13 0.05 eq. RhCI(/-Pr2P)2

C3H 3π7

Et 3 N, benzene, 50 °C 20 h, 58% 40

41

Under thermolysis conditions, cyclization of l,3-hexadiene-5-ynes occurs to give substituted arenes in a similar fashion to the Bergman cyclization. This variation on the Bergman cyclization is known as the Hopf cyclization.32 At temperatures up to 550 °C the cyclic intermediate (43) in the Hopf cyclization is believed to possess strong diradicai character, and so has a lot in common with the Bergman cyclization.33 Indeed the latter intermediate 43 may be trapped through reaction with various reagents just as in the Bergman cyclization.34

200-250 °C

43

O'Connor and co-workers have shown that the Hopf cyclization can be carried out efficiently under very mild conditions (23 °C) when dienyne 45 is treated with ruthenium complex 24 in THF-c/g or CDCI3.24

218

Name Reactions for Carbocyclic Ring Formations Cp*Ru

+

RuCp* 24

45

CDCI3 23 °C 50 min 96%

n-Pr

n-Pr 46

4.2.5 Synthetic Utility Until relatively recently, interest in the Bergman cyclization had been restricted due to its limited substrate scope and the availability of more practical methods for substituted arene construction. Since 1987 with the discovery of natural enediynes that possess cytotoxic activity, there has been a great surge in studies of the Bergman cyclization, specifically with respect to the mode of action of the natural enediynes. A number of these natural products were found to undergo Bergman cyclization under much milder conditions (37 °C or lower) than previously thought possible. *

,NHC02Me HO.-.^l-^

( \.,NHC02Me

.

HO

48

HS:

:Nu Calicheamicin 47

Sugar

DNA NHC02Me

Sugar 50

DNA cleavage

49

Sugar

Calicheamicin γι1 47 has been proposed to act as an antitumor antibiotic by the mechanism shown.8'3 '40 The enediyne system 47 is

Chapter 4 Six-Membered Carbocycles

219

triggered to aromatization via Bergman cyclization after nucleophilemediated cleavage of the methyltrisulfide group of 47 and intramolecular conjugate addition. The change in hybridization from sp2 to sp at the bridgehead position (on going from 47 to 48) is critical to the success of the cyclization. This change causes a shortening of the distance between the acetylenic groups (known as the cd distance) and hence lowers the activation energy sufficiently for spontaneous cyclization of 48 to occur at physiological temperature.6'8 Through atom-transfer experiments it has been determined that diradicai species 49B abstracts hydrogen atoms from duplex DNA leading to cleavage of both strands of DNA and, as a result, cell death.40 Dynemicin also displays significant cytotoxicity through a similar mechanism involving a Bergman cyclization-generated diradicai species.4'38 Neocarzinostatin's biological activity relies on the involvement of the Myers-Saito cyclization. Its mode of action involves the generation of a diradicai species that causes DNA cleavage.37 4.2.6 Experimental Thermal Bergman cyclization: c/s-2,3-Bis(hydroxymethyl)-l,2,3,4tetrahydronaphthalene (8)8 OH

1,4-cyclohexadiene

0 H

benzene, 70 °C 4 h, 52%

A solution of 7 (38.0 mg, 0.20 mmol) in 1,4-cyclohexadiene (1.90 mL, 20.0 mmol) and degassed benzene (20 mL) was heated at 70 °C for 4 h. The reaction mixture was concentrated, and the residue was purified by preparative thin-layer chromatography (5% methanol in dichloromethane) to afford 20.0 mg (52%) of 8 as a white solid. Photo-Bergman cyclization: 2,4-Dimethoxy-6,7,8,9-tetrahydro benzo[g]quinazolin-6-ol (52)13 OH

OCH3 hv ;-PrOH,40°C 24 h, 82%

H 3 CCT^N

52

OH

Name Reactions for Carbocyclic Ring Formations

220

Photolysis of 51 was performed using a Rayonette photochemical reactor equipped with 16 3100 À lamps. A 0.01 M potassium chromate (K^CrC^) solution was used to filter out the 313 nm wavelength. A solution of 51 (2.58 mg, 0.01 mmol) in degassed /-PrOH (10 mL) was stirred at 40 °C for 24 h. The solvent was then evaporated under reduced pressure. The resulting residue was purified by column chromatography (S1O2, hexane/ethyl acetate, 3 : 1 ) , from which pure 52 (82%) was obtained. Metal-promoted Bergman cyclization: [(1,2,3,4,5-η)-1,2,3,4,5pentamethyl-2,4-cyclopentadien-l-yl}Ru{(3a,4,5,6,7,7a-T|)-2,3dihydro-6-methyl-lH-inden-5-yl)trimethylsilane}]OTf(30)24 Cp*Ru + 24

TMS 28

2™C 77 o /o

~

^

™S

30

[Cp*Ru(CH3CN)3]OTf (24, 16 mg, 0.031 mmol) was added to a solution of 28 in THF (ca. 10 mL) at room temperature. An immediate change of solution color from clear to light orange, with progressive darkening, was observed. After 1 h, the volatiles were removed in vacuo to yield a black residue. The residue was then dissolved in a minimum amount of dichloromethane, and ether was added to give 14.2 mg (77%) of 30 as a brown solid. 4.2.7 21. 22. 23. 24. 25. 26. 27. 28. 29. 30. 31. 32. 33. 34.

References Jones, R. R.; Bergman, R. G. J. Am. Chem. Soc. 1972, 94, 660-661. [R] Bergman, R. G. Ace. Chem. Res. 1973, 6, 25-31. Lockhart, T. P.; Bergman, R. G. J. Am. Chem. Soc. 1981, 103, 4091^1096. [R] Basak, A.; Mandai, S.; Bag, S. S. Chem. Rev. 2003, 103, 4077^094. Lewis, K. D.; Matzger, A. J. J. Am. Chem. Soc. 2005,127, 9968-9969. Nicolaou, K. C; Zuccarello, G.; Ogawa, Y.; Schweiger, E. J.; Kumazawa, T. J. Am. Chem. Soc. 1988,770,4866^1868. Nicolaou, K. C; Ogawa, Y.; Zuccarello, G.; Kataoka, H. J. Am. Chem. Soc. 1988, 110, 7247-7248. Nicolaou, K. C; Zuccarello, G.; Riemer, C; Estevez, V. A.; Dai, W.-M. J. Am. Chem. Soc. 1992,774,7360-7371. Turro, N. J.; Evenzahav, A.; Nicolaou, K. C. Tetrahedron Lett. 1994, 35, 8089-8092. Funk, R. L.; Young, E. R. R.; Williams, R. M.; Flanagan, M. F.; Cecil, T. L. J. Am. Chem. Soc. 1996, 775, 3291-3292. Evenzahav, A.; Turro, N. J. J. Am. Chem. Soc. 1998, 720, 1835-1841. Kaneko, T.; Takahashi, M.; Hirama, M. Angew. Chem., Int. Ed. Engl. 1999, 38, 1267-1268. Choy, N.; Blanco, B.; Wen, J.; Krishan, A.; Russell, K. C. Org. Lett. 2000, 2, 3761-3764. Pandithavidana, D. R.; Poloukhtine, A.; Popik, V. V. J. Am. Chem. Soc. 2009, 737, 351-356.

Chapter 4 Six-Membered Carbocycles 35. 36. 37. 38. 39. 40. 41. 42. 43. 44. 45. 46. 47. 48. 49. 50. 51. 52. 53. 54. 55. 56. 57. 58. 59. 60.

221

König, B.; Rutters, H. Tetrahedron Lett. 1994, 35, 3501-3504. König, B. Schofield, E.; Bubenitschek, P.; Jones, P. G. J. Org. Chem. 1994, 59, 7142-7143. Warner, B. P.; Miller, S. P.; Broee, R. D.; Buchwald, S. L. Science 1995,269, 814-816. König, B.; Hollnagel, H.; Ahrens, B.; Jones, P. G. Angew. Chem., Int. Ed. Engl. 1995, 34, 2538-2540. Basak, A.; Shain, J. C; Khamrai, U. K.; Rudra, K. R. J. Chem. Soc., Perkin Trans. 1 2000, 1955-1964. Basak, A.; Shain, J. C. Tetrahedron Lett. 1998, 39, 1623-1624. Basak, A.; Shain, J. C. Tetrahedron Lett. 1998, 39, 3029-3030. Rawat, D. S.; Zaleski, M. J. Am. Chem. Soc. 2001,123, 9675-9676. O'Connor, J. M.; Lee, L. I.; Gantzel, P. J. Am. Chem. Soc. 2000,122, 12057-12058. O'Connor, J. M.; Friese, S. J.; Tichenor, M. J. Am. Chem. Soc. 2002,124, 3506-3507. O'Connor, J. M.; Friese, S. J.; Rodgers, B. L. J. Am. Chem. Soc. 2005, 127, 16342-16343. Nagata, R.; Yamanaka, H.; Okazaki, E.; Saito, I. Tetrahedron Lett. 1989, 30,4995-^1998. Myers, A. G.; Kuo, E. Y.; Finney, N. S. J. Am. Chem. Soc. 1989, 111, 8057-8059. Myers, A. G.; Dragovich, P. S. J. Am. Chem. Soc. 1989, 111, 9130-9132. Nagata, R.; Yamanaka, H.; Murahashi, E.; Saito, I. Tetrahedron Lett. 1990, 31, 2907-2910. Wang, Y.; Finn, M. G. J. Am. Chem. Soc. 1995,117, 8045-8046. Ohe, K.; Kojima, M.; Yonehara, K.; Uemura, S. Angew. Chem., Int. Ed. Engl. 1996, 35, 1823-1825. Hopf, H.; Musso, H. Angew. Chem., Int. Ed. Engl. 1969, 8, 680. Zimmermann, G. Eur. J. Org. Chem. 2001, 457^171. Hopf, H.; Berger, H.; Zimmermann, G.; Niichter, U.; Jones, P. G.; Dix, I. Angew. Chem., Int. Ed. Engl. 1997, 36, 1187-1190. Lee, M. D.; Dunne, T. S.; Siegel, M. M.; Chang, C. C; Morton, G. O.; Borders, D. B. J. Am. Chem. Soc. 1987, 109, 3464-3466. Lee, M. D.; Dunne, T. S.; Chang, C. C; Ellestad, G. A.; Siegel, M. M.; Morton, G. O.; McGahren, W. J.; Borders, D. B. J. Am. Chem. Soc. 1987,109, 3466-3468. Myers, A. G.; Proteau, P. J.; Handel, T. M. J. Am. Chem. Soc. 1988, 110, 7212-7214. Konishi, M.; Ohkuma, H.; Tsuno, T.; Oki, T. J. Am. Chem. Soc. 1990,112, 3715-3716. De Voss, J. J.; Hangeland, J. J.; Townsend, C. A. J. Am. Chem. Soc. 1990, 112, 4554-4556. De Voss, J. J.; Townsend, C. A.; Ding, W.-D.; Morton, G. O.; Ellestad, G. A.; Zein, N.; Tabor, A. B.; Schreiber, S. L. J. Am. Chem. Soc. 1990, 112, 9669-9670.

222

4.3

Name Reactions for Carbocyclic Ring Formations

Bogert-Cook Reaction

Timothy T. Curran 4.3.1

Description

The Bogert-Cook reaction is the reaction of a hydroxy-substituted phenyl alkane 1 or phenyl substituted alkene 2 with an acid, Lewis acid or dehydrating agent (except for phosphorus-containing acids or dehydrating agents, i.e., H3PO4 or PPA, which will be reserved for the Bardhan-Sengupta reaction) to generate a carbocationic species which then undergoes electrophilic aromatic substitution (EAS) and proton elimination to provide the corresponding dihydroindene (« = 1), tetrahydronapthalene (n = 2), or tetrahydrobenzo-[7]-annulene (n = 3). While reactions of n = 1 or 3 have been reported, there are limitations to delivering the n = 1 or 3 products in high yield due to cation migration, which generates the preferred tetrahydronapthalene. In addition, due to the cationic nature of the reaction, there can be an array of by-products generated, depending on the stability of the carbocation and neighboring groups. Due to the mechanistic nature of the reaction, the hydroxyl group or alkene need not be at the site of aryl attack. Cyclization is not the preferred reaction observed when the hydroxyl or alkene is located at the benzylic position of the cyclizing ring. 4.3.2

Historical Perspective

In 1933, Carston Bogert reported the synthesis of phenanthrene from either tertiary or secondary alcohol 5 or 7 via dehydration with dilute H2SO4, providing common alkene 6. Cyclization with cone. H2SO4 provided the octahydrophenanthrene 8 and ultimately dehydrogenation with elemental selenium completed the synthesis of phenanthrene 9.1 His group followed

Chapter 4 Six-Membered Carbocycles

223

with a full paper in 1936 describing this work in more detail.2 During a similar time period, Cook and co-workers reported the analogous cyclization and dehydrogenation as well as application toward preparing the carbon framework of the steroidal backbone.3 In this work, Lewis and protic acids were used on both alcohols and alkenes to promote the cyclization. Work in the Cook group demonstrated that the cyclization of alkene 10 yielded the incorrect regiochemistry for the angular methyl group in the steroidal backbone, compound 11, in 68% yield.

Both the Bogert and Cook groups continued to develop the scope and limitations of these cyclizations and other groups joined the task. During this work, two different spirocycles were reported to be formed. The first at the tertiary alcohol carbon, derived from the point of attachment of the phenylpropanyl moiety. For example, closure to form the six-membered spirocyclic ring for two compounds was reported4 to occur in about 90% yield from alcohols 12 and 14.

12

13

14

15

Name Reactions for Carbocyclic Ring Formations

224

The second type of spirocyclic system resulted from attack of the aromatic ring on the site of attachment of the phenethyl group, which was not necessarily desired. Initially, the regioselectivity of the cyclization conditions were thought to greatly affect the spirocyclic formation but this was discredited by some experiments in the Cook group3'5 and others, showing that substitution of the alkene with a methyl group or carboxyl group6 mitigated this type of spirocyclic formation rather than the acid used. For example, cyclization of 16 gave the desired six-membered cyclized adduct in poor yield (27%) presumably due to an appreciable amount of spirocyclic compound 18 formation,33 while cyclization of alkene 10 provided compound 11 in 68%. The type of acid used has more recently been thought to alter the eis Itrans product ratio.7

16

17

18

An alkyl carboxyl group (e.g., ester) juxtaposed to the hydroxyl group or the forming carbocation was reported to minimize the amount of spirane formation (resulting from cyclization at the point of attachment of the phenethyl group) due to protonation of this neighboring group, which would require dication formation before cyclization.6'7 It should be noted that only aromatic rings containing EDG were successful in cyclization with a juxtaposed carboxylate. Six-membered ring formation was shown to be the preferred mode of cyclization. The observation that the reaction was carbocationic in nature was demonstrated by the formation of products, which were best explained by Wagner-Meerwein rearrangement followed by cyclization (vide infra). Tertiary alcohols reportedly reacted and cyclized faster than secondary alcohols. While some primary alcohols were reported to undergo cyclization at the primary carbon, terminal alkenes have provided the intermediate secondary carbocation that cyclized.7 4.3.3

Mechanism

The mechanism of the Bogert-Cook reaction has been shown to be substrate dependent and different transition states have been used to explain different products observed. However, in general, starting with an alcoholic substrate 19a,b, protonation of the hydroxyl group and loss of water to generate the carbocation 20a,b (which could either result in alkene formation, cyclization,

Chapter 4 Six-Membered Carbocycles

225

or carbocation migration) has been proposed. If energy exists in the system to overcome ring and A-strain encountered during the cyclization, then electrophilic aromatic substitution takes place, resulting in a new C-C bond and a phenylcation 22. Loss of a proton to rearomatize provides product 23. As can be seen, with the formation of the tertiary carbocation 20b, cyclization would provide the spirane.

While electron-donating groups are not required on the aromatic ring, as one might expect electron-withdrawing groups might hinder or stop the reaction. When the aromatic ring is electron rich, cyclization is suggested to be less selective providing more spirane.7 Initially, Bogert proposed that this reaction always went through an alkene intermediate due to the observation that when the reaction was stopped (quenched before completion) the presence of an olefinic substrate was supported by 30-A0 mol % uptake of Br2,8 while others have thought alkene or carbocation formation unnecessary. An alternative mechanism for some substrates has been proposed in light of experimental results. The key experiments for this alternative mechanistic view was done by Barnes and Olin, wherein they described the reaction of /raws-racemic and transoptically-enriched alcohol 24 with 90% H2SO4 to provide mainly the cisisolated product 25 which when optically enriched 24 was used, the product 25 rotated plane-polarized light. These results suggested that an alternative mechanism without free cation formation and/or intermediate alkene formation was possible.9

226

Name Reactions for Carbocyclic Ring Formations

ΌΗ

90% H2S04 * 63-74%

24

These authors and others proposed a bridged cationic intermediate 28. Thus, for the Bogert-Cook reaction, three potential intermediates have been postulated to provide product: activated hydroxyl as a leaving group 26, free cation formation 27, and a bridged cationic hydrogen species 28. The bridged cationic species could be viewed as "partial Wagner-Meerwein" rearrangement or "H stabilization" of the formed cation.10

©

/ 0 \ © 26

H© 28

27

Of these three proposals, structures 27 and 28 are the more likely intermediates for the cyclization. The stability of the formed cation, the reaction conditions, and the stereoelectronic factors for cyclization are all thought to contribute to determining which of the two intermediates best represents the mechanistic path for each reaction. Evidence for cation formation was partly derived by the observation that for i-butyl substituted carbinols, rearrangement occurs to cleanly provide the tetralin or indane. For example, either 29 or 31 reacted with 90% H2SO4 to provide the tetralin. Compound 30 resulted from either Me or H 1,2shift.11 r

-^v^\

H0 29

90% H2S04 f ^ Y ^

>MI

Me

55%

90% H2S04

^^y<^Me Me

30

Me

86%

f

'-γΊ

,Me

^ M e ^ HO Me 31

4.3.4 Selectivity Regioselectivity

There is a preference for the formation of the six-membered ring presumably due to increased torsional strain in the transition state to form the 5-

Chapter 4 Six-Membered Carbocycles

227

memberred ring in comparison to the formation of the 6-membered ring. It was first noted by Bogert and co-workers8 that having the hydroxyl group on the 4th carbon from the phenyl ring provided the highest yield of the tetralin. When there was Me (alkyl) substitution at C3 (with the exception of formation of a tertiary carbocation at the 4th carbon from the cyclizing ring—for example, see conversion of 31 into 30), then both the indane and tetralin were formed. Many of these experiments were later repeated by Kalifand Roberts who also reported the cyclization of 1-phenyl 3- or 4-Mesubstituted pentanols with H2SO4. For these cyclizations, the formation of the tetralin predominated over the formation of the indane.12

^V^Y

^J

32

,Me β

ΛθΗ

85% H 2 S0 4> 75%

Me Me 0 H

33, 31 %

34, 15%

34%

10%

56%

36%

16%

47%

85% H2SQ4> 73%

OH Me

85% H2SQ4> 28%

The low yield for the cyclization of 37 was presumably due to polymerization after benzylic cation formation. Additional substrates were prepared to further examine the preference for 6-membered ring formation. Specifically, 5,6-diphenyl-2-hexene 38 was treated with 85% H2SO4 and yielded only the 6-membered ring products 39 and 40 in an 87:13 ratio.

85% H 2 S0 4 60%

38

Me 39, 87%

Me 40, 13%

228

Name Reactions for Carbocyclic Ring Formations

One could obtain both five- and seven-membered ring formation but only the 6-membered ring was observed. Furthermore, formation of the sixmembered ring 39 was preferred > 6:1 (cyclization of ring z onto carbon b over cyclization of ring y on carbon a) over 40 presumably due to increased 1,3- steric interactions in forming 40. Reaction of a substrate similar to 38, having the methyl group on carbon 2 of a 4,5-diphenyl-pentene, presumably forming a tertiary carbonium ion, which could cyclize to either the five- or six-membered ring, reportedly gave the six-membered ring product 42. Again this illustrates the preference for the formation of the 6-membered ring over the five-membered ring. 85% H 2 S0 4 65% Me

41

42

Me

Furthermore a preference of cyclization to a five-membered ring in comparison to the seven-membered ring by reaction of a 4, 6-diphenyl-2methyl-2-hexanol 43 with H2SO4 provided an 85% yield of 44 with no detectable 7-membered ring formed. Me

85% H 2 S0 4 85%

The "forced" formation of a seven-membered ring was accomplished, albeit in poor yield. Treatment of diphenyl substituted pentanol 45 with either 85% H 2 S0 4 or A1C13 in MeN0 2 gave 10-15% yield of tetrahydrobenzo-[7]-annulene 46. 85% H 2 S0 4 or AICI3, MeN0 2 ^-

10-15%

Chapter 4 Six-Membered Carbocycles

229

Stereoselectivity In simple systems, cyclization to the c/s-fused octahydrophenanthrene has been reported as the major product. Furthermore, it was reported that stronger acidic conditions diminished the selectivity.13 For example, compound 47, when treated with 85% H2SO4, reportedly gave < 20% trans 49 when compared to the amount of trans compound formed using 90% H2SO4.

H 48, >80%

H 49, <20%

The stereochemistry of the carbinol was also shown not to affect the stereochemistry of cyclization. This was reported during the synthesis of estrone by Johnson and co-workers.14 Whether 50 or 51 was taken into the cyclization, a similar ratio of isomerie products was obtained.

AICI, HCI, PhH 45% 3 isomerie forms 52

This same notion had previously been reported by Barnes and coworkers in a variety of systems.7 Ireland and co-workers later applied conformational and approach vector considerations to rationalize the observed stereochemical outcome of reactions. 15

Name Reactions for Carbocyclic Ring Formations

230

Me OH R

1

R

Me

85% H 2 S0 4 ; P P A o r P 2 0 5 , PhH

R-,1 R^ 2

2

53, Ri — R2 — R3 — H 54, R1 = R2 = Me; R3 = OMe 55, RT = C0 2 H; R2 = Me, R3 = H

56, 20% 57, 24% 58, 30%

59, 76% 60, 60% 61,30%

While the c/s-product predominates, the origin of this preference for 59 and 60 are thought to be due to a combination of A 1,2 strain, torsional strain, steric approach of the aromatic ring in the transition state, and secondary stabilization effects of the intermediate.

i=> 0

trans

eis

Two possible transition states leading to the eis product are depicted in 62 and 63. In the case of the cyclization of 53, having the phenethyl group axial should be the preferred or should have a lower energy transition state (TS) depicted as 63. The torsional strain, which accompanies cyclization via transition state 62 or 64 was presumed to be higher than 63. Whereas for the cyclization of 54 via TS 63, the adjacent gem dimethyl substituted carbon should act as a deterrent for eis ring formation via 63, therefore, diminishing the amount of eis product. Cyclization of 55 provides a 1:1 mixture of cisand /raws-isomers. Analogous arguments were used to rationalize the outcome of that reaction with a slight twist introduced due to the participation or stabilization of the adjacent carboxylate. For this interaction to occur, the carboxylate needs to be an axial substituent to stabilize the TS and the ring flip of 62 is likely a contributing conformer. Another important point noted by the authors was the potential for olefin formation and that in

Chapter 4 Six-Membered Carbocycles

231

the presence of a neighboring asymmetric center (i.e., the asymmetric center in 54) the stereochemistry of protonation of the alkene could have a significant effect on the product. It is interesting that there have been reports in which the cyclization reaction did not proceed due to stereochemical considerations. For example, while the model system for the cyclization of 65 to a mixture of 66 and 67 was reported in good yield, the attempted cyclization of 68 did not proceed at all. In this case the authors suggested that the cyclization required a twist boat transition state of the existing cationic ring. The trans-fused decalin system renders such transition state inaccessible, and the elimination product was formed. Further proof that this just is not simply due to steric interactions came from the attempted cyclization of 69, which again gave rise only to the elimination product 71. 16

Me

OMe

Me

MeO

O IR2 P H Me

see text R, OMe

68, R-, = H,R 2 = OH 69 Ri = R2 = O

4.3.6

70, R-, = H , R 2 = OCOH 71, Ri = R2 = 0

Variations and Synthetic Utility

General Variations in Conditions and Substrates A variety of acids and Lewis acids have been described to promote the cyclization from either the alkene or hydroxy compound. While H2SO4 was the first reported agent, mixing organic and mineral acids like HCO2H or AcOH with H2SO4 has been utililized. Other mineral acids include HBr, HCl and HF.17 For example, cyclization of a ketone substrate 72 provided the cyclized material 73 in 87% yield.

Name Reactions for Carbocyclic Ring Formations

232

C0 2 Et HF 0 °C, 5 min 87%

73

Use of a mineral acid to promote cyclization to an amine-containing substrate yielded the bicyclic alkaloid-skeleton 75 in 62% yield.1 Reports of cyclization to such bicyclic systems have been limited. 48% HBr 62%

MeO 74

Me

VNMe HO-

Λ /L Me 75

Lewis acids have been limited to just a few, including AICI3 and SnCU. For example, cyclization of amide 76 provided a high yield of the cyclized product 77.19 Similar conditions have been applied to similar substrates in preparation of experimental therapeutics in the pharmaceutical industry.20

Me Me'

Me Me

Me

AlCh

Me Me. Me

heat, 25 min 97%

76

Many alternatives exist, including the lanthanide series of Lewis acids, which should mildly promote the chemistry. The addition of cosolvents has been reported, but due to the harshly acidic conditions, choices are limited to solvents robust to withstand the acidic conditions.7 Variation in the Leaving Group In addition to alkenes or alkanols, ketone 72, can be dehydrated as easily as an alcohol providing an alkene after cyclization (see compound 73). Other leaving groups, which can provide a cationic species would also be able to promote cyclization; carboxylic acids could serve this role,21 epoxides or

Chapter 4 Six-Membered Carbocycles

233

alkyl halides. For example, cyclization with epoxide opening has been shown to provide good yield of the resulting tetrahydronapthalene. Cyclization to form the six-membered ring was reported as the predominant product for these cyclizations.22 Thus SnCU promoted cyclization of 78 and provided the primary alcohol 79 in 85% yield. The authors suggest an SN2like TS, in which the epoxide stabilizes the TS. Cyclizations using epoxide substrates should lend itself to the introduction of asymmetric centers.

79 OH

As one might expect, halides serve as good substrates, and FriedelCrafts type alkylations have been reported.7'23 In this instance, the cyclization product ratio and yield at similar temperature (25 °C) proved dependent on the solvent. In either case, acceptable yield of the desired products were obtained; the doubly cyclized product was suggested to arise from compound 81 after Lewis acid induced cation formation and further cyclization.

solvent product ratio 81 82 Pet Ether

47:15

CS2

76:10

4.3.7 Experimental 85% H2S04 83%

Me 84

Me

234

Name Reactions for Carbocyclic Ring Formations

Preparation of 1,1-Dimethyl Tetralin (84)24 The procedure described by Bogert and co-workers was essentially followed for tertiary alcohols. One volume of alcohol was dropped into a cooled solution of 85% H2SO4 with good stirring while maintaining the temperature < 10 °C. After addition, the reaction appeared complete but was allowed to warm to room temperature and stirred for an additional hour. While Bogert reported diluting with 10-15 volumes of water and distilling, Roberts's modification was to dilute with water and extract with ether. The ether layer was separated, washed with 10% sodium carbonate solution, followed by water, dried over anhydrous sodium sulfate, and finally distilled. For compound 84, 83% yield, b.p. = 88 °C at 8-10 mm Hg. Secondary alcohols could be dehydrated using 85% H2SO4 but by using 90% H2SO4 or by treatment with 85% H 2 S0 4 with warming to 35^10 °C, the cyclized product could be realized. Primary alcohols gave best yield when H3PO4 was used. This is covered in Section 4.1. 4.3.8 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18. 19. 20. 21. 22.

References Bogert, M. T. Science 1933, 77, 289. Perlman, D.; Davidson, D.; Bogert, M. T. J. Org. Chem. 1936, 288-299. (a) Cook, J. W.; Hewett, C. L. J. Chem. Soc 1933, 1098-1112. (b) Cohen, A.; Cook, J. W.; Hewett, C. L.; Girard, A. J. Chem. Soc. 1934, 653-658. Perlman, D.; Davidson, D.; Bogert, M. T. J. Org. Chem. 1936, 300-304 Barnes, R.; Hirsheler, H. P.; Bernstein, B.R. J. Am. Chem. Soc. 1952, 74, 32-34. Sterling, E. C; Bogert, M. T. J. Org. Chem. 1939 4, 20-28. [R] Barclay, L. R. C. In Friedel-Crafts and Related Reactions, Vol. 2, Part II, Olah, G. A., ed., Wiley, New York, NY, 1964, pp 785-977. Roblin, R. O.; Davidson, D.; Bogert, M. T. J. Am. Chem. Soc. 1935, 57, 151-159. Barnes, R. A.; Olin, A. D. J. Am. Chem. Soc. 1956, 78, 3830-3833. Barnes, R. A. J. Am. Chem. Soc. 1953, 75, 3004-3008. Price, D.; Davidson, D.; Bogert, M. T. J. Org. Chem. 1938, 540-545. Khalaf, A. A.; Roberts, R. M. J. Org. Chem. 1972, 37, 4227-4235. (a) VandeKamp, J.; Mosettig, E. J. Am. Chem. Soc. 1936, 58, 1062-1063. (b) Barnes, R. A.; Beachem, M. T. J. Am. Chem. Soc. 1955, 77, 5388-5390. (c) Rarnes, R. A.; Gottesman, R. T. J. Am. Chem. Soc. 1952, 74, 35-37. Johnson, W. S.; Banerjee, D. K.; Schneider, W. P.; Gutsche, C. D.; Shelberg, W. E.; Chinn, L. J. J. Am. Chem. Soc. 1952, 74, 2832-2849. Ireland, R. E.; Baldwin, S. W.; Welch, S. C. J. Am. Chem. Soc. 1972, 94, 2056-2066. Brisse, F.; Lectard, A.; Schmidt, C. Can. J. Chem. 1974, 52, 1123-1134. Adkins, H.; Hager, G. F. J. Am. Chem. Soc. 1949, 71, 2965-2968. Eddy, N. B.; Murphy, J. G.; May, E. J. Org. Chem. 1957, 22, 1370-1372. Smith, L. I.; Prichard, W. W. J. Am. Chem. Soc. 1940, 62, 778-780. Andreana, T. L.; Cho, S. S. Y.; Graham, J. M.; Gregory, T. F.; Howard, H. R.; Kornberg, B. E.; Nikam, S. S.; Pflum, D. A. WO 2004/026864, April 1, 2004. Smith, L. I.; Spillane, L. J. J. Am. Chem. Soc. 1943, 65, 202-208. Taylor, S. K.; Hockerman, G. H.; Karrick, G. L.; Lyle, S. B.; Schramm, S. B. J. Org. Chem. 1983, 48, 2449-2452.

Chapter 4 Six-Membered Carbocycles 23. 24.

235

Roberts, R. M; Anderson, G. P.; Khalaf, A. A.; Low, C.-E. J. Org. Chem. 1971, 36, 33423345. Khalaf, A. A.; Roberts, R. M. J. Org. Chem. 1969, 34, 3571-3574.

236

4.4

Name Reactions for Carbocyclic Ring Formations

Bradsher Cycloaddition and Bradsher Reaction

Paul Galatsis 4.4.1

Description

The Bradsher cycloaddition1 is formally a [4+ + 2] cycloaddition of quaternary aza-aromatic cations with dienophiles. Specifically, the reaction proceeds by an inverse electron demand Diels-Alder reaction in which the diene conatins a cationic aza-diene moiety. o

/v©/v

^

i^N'^Y^i ^ ί ^ ^ Χ ^

Λ s

o AcOH Δ

/

,

JÌ

„0

0=\ /

©Y N-

ττ^

In the literature, the Bradsher name has also been associated with cyclodehydration reactions that give rise to fused aromatic ring systems. The Bradsher reaction2 uses acidic conditions on diarylmethane carbonyl compounds to facilitate the ring closing process.

4.4.2

Historical Perspective

When first reported by Bradsher and Solomons in 1957,3 this reaction represented the first example of a Diels-Alder reaction in which the diene was a quaternary ammonium salt. The reaction of acridizinium bromide with now classical dienophiles, e.g., maleic anhydride, malonate or fumarate esters and acrylonitrile was found to afford the expected Diels-Alder adducts. However, benzoquinone failed to generate any of the predicted products. While the concept of an inverse electron demand Diels-Alder reaction had theoretically been hypothesized much earlier,4 this was the first practical example of such a reaction.

Chapter 4 Six-Membered Carbocycles

4.4.3

237

Mechanism

The Bradsher reaction is formally a [4+ + 2] Diels-Alder reaction. However, as a consequence of the aza cationic nature of the diene, this reaction proceeds by the inverse electron demand manifold. The classical DielsAlder reaction employs the partnering of an electron-rich diene and an electron-deficient dienophile to provide the proper interaction of the highest occupied molecular orbital (HOMO) and lowest unoccupied molecular orbital (LUMO) as prescribed by frontier molecular orbital theory (FMO)5 to generate the observed adducts. Thus FMO theory interprets this reaction proceeding via the HOMO of the diene with the LUMO of the dienophile. In the case of the inverse electron demand reaction, the electronics of the reaction are inverted. Therefore, in the Bradsher reaction, the electrondeficient aza cation diene's LUMO interacts with the HOMO of an electron rich dienophile. This mechanistic pathway provided a rationalization for the lack of reactivity of the electron-deficient tetracyanoethylene (TCNE), while electron-rich styrenes afforded the predicted product from reaction of 1 to generate 2.6

As the substituents on the styrene increase electron density on the alkene moiety the reaction rate increases (see Table 1). This is consistent with FMO theory associated with the inverse electron demand Diels-Alder reaction. As one increases the electron density on the dienophile, the energy of the HOMO also increases and narrows the energy gap with the LUMO of the diene. Thus allowing the reaction to proceed with greater efficiency and a concomitant increase in reaction rate. Table 1. Effect of Substituents on Rate of Cycloaddition R rate /7-NO2 2.0 H 5.8 p-Me 9.8 /?-MeO 25

238

Name Reactions for Carbocyclic Ring Formations

Additional mechanistics studies have also been published.7 A Hammett linear free energy relationship was found to exist with the greatest correlation using σ ρ substituent constants. While these data tended to imply a two-step mechanistic pathway, with initial bond formation proximal to the cationic nitrogen atom, further multiparametric linear free energy relationships and an analysis using FMO confirmed the polar cycloaddition reaction pathway, albeit in an asynchronous fashion. In addition, the potential for a charge transfer complex preceding the cycloaddition transition state was consistent with the observed data. Most recently,8 an analysis of the reaction using DFT calculations at the B3LYP/6-31G(d) level add additional support for a reactant-like transition state with asynchronous bond formation. 4.4.4

Variations and Improvements

Most examples of the Bradsher cycloaddition reaction have utilized fused polycyclic aromatics as the cationic aza-diene fragment. Falck and coworkers9 have reported that one can carry out this reaction using monocyclic quaternary aza-aromatics. The application of this methodology was illustrated using the JV-(2,4-dinitrophenyl) salt of N,iV-diethylnicotin-amide 3 and ethyl nicotinate 4 in conjunction with enol ethers. The reaction proceeded at room temperature to generate adducts 5. This was the result of the exo-addition at the C2-C5 positions of the pyridyl ring. The resultant iminium ion was then trapped by the methanolic solvent.

3 R = NEt2 4 R = OEt

As alluded (vide supra), some confusion may arise with respect to this named reaction as there is reference in the literature to an alternative reaction with the same name. The Bradsher reaction2 forms aromatic rings but via an acid-catalyzed Friedel-Crafts-like process. Thus diaryl-methanes having a carbonyl group in the ortho position can undergo a cyclodehydration reaction to generate the corresponding anthracene derivatives. In this respect, the Bradsher reaction is related to the Elbs reaction,10 which involves the pyrolytic cyclization of diaryl ketones 6 having an ortho methyl or methylene substituent for the formation of polycyclic aromatics 7.

Chapter 4 Six-Membered Carbocycles

239

Θ H

For R] = R.2 = H, alkyl, the reaction is classified as the proper Bradsher reaction. If R2 = aryl, the variation has been classified as the Vingiello process. 11 There has been some discussion in the literature as to the mechanistic pathway for these variations and two mechanisms remain to be resolved.12 4.4.5 Synthetic Utility Bradsher cycloaddition reaction

Initially, the Bradsher cycloaddition reaction was used to gain greater understanding of the Diels-Alder reaction. More recently it has found utility in the constuction of carbon frameworks that provided novel entries into the synthesis of natural products. For example, the Bradsher cycloaddition reaction has been reported on the use of isoquinolinium salts for the stereocontrolled synthesis of substituted tetralins 13 Reaction of

240

Name Reactions for Carbocyclic Ring Formations

isoquinolinium salts 8 (Ar = 2,4-dinitrophenyl) with enol ethers 9, initially afforded adduct 10, which was trapped by solvent to generate the azabicyclo[2.2.2] 11. Exposure to acidic conditions transformed 11, via aminol hydrolysis, into tetralins 13. If the process was carried out under acidic aqueous conditions, then naphthalenes 12 were obtained by aromatization of the ring opened species. O

OH C0 2 Me

HOv

The secondary metabolite vineomycinone B2 methyl ester, 14, which displayed antitumor/antibiotic activity and has a pharmacophore similar to the anthracyclines, was prepared using a double Bradsher cycloaddition reaction process.14 This convergent strategy began with the cycloaddition reaction of salt 15 and enol ether 16. The adduct 17 was produced after intramolecular trapping by the pendant alcohol functionality. Unmasking of the right-hand portion of the molecule affored 18, which was set up to execute a second Bradsher cycloaddition reaction. Formation of the 2,4dinitrophenyl salt preceded cycloaddition with enol ether 19. Acid-catalyzed unmasking of the left-hand portion of the molecule generated 20, which was elaborated into 14. „»OBPM CaCCh MeOH CH2CI2 17

1. CNBr NaHC0 3 MeOH 2. HCI THF

CHO OBPM

18

Chapter 4 Six-Membered Carbocycles

241

CaC03 MeOH 3. HCI.THF

In a convergent approach to the nogalamycin members of the anthracycline family of antibiotics, two cycloaddition reactions were used in the construction of a CDEF-ring analog, 22, of nogalamycin, 21. 1 5 A nitrile oxide furan [3 + 2] cycloaddition was used in the construction of heterocycle 24. This advanced intermediate was partnered with the isoquinolium salt 23 for participation in a Bradsher cycloaddition reaction. Standard conditions for this reaction did not afford any of the desired product. It was determined that high-pressure conditions were required to drive the reaction manifold toward the requisite intermediate 25 after unmasking of the cycloadduct.

242

Name Reactions for Carbocyclic Ring Formations

The Franck group16 has also reported on the use of the Bradsher cycloaddition reaction for the generation of a functionalized B-ring of angucycline antibiotic sakyomicin A, 26. Their approach began with the cycloaddition reaction of 27 with the TBDMS enol ether of acetaldehyde to generate adduci 28. A short sequence transformed this compound into 29, the first synthetic model for the dihydronaphthalene framework of 26.

CHO OTBDMS

^ \ /

0

CH(OMe)2 OTBDMS

29

In a series of papers, the Langlois group reported multiple strategies toward the construction of manzamine A, 30. An approach to the construction of the ABC tricyclic core framework, 31, employed the Bradsher cycloaddition reaction as the key synthetic step. Thus reaction of isoquinolium salt 32 with ethyl vinyl ether under standard reaction conditions afforded the cycloadduct 33. The advanced intermediate 31 was then generated in six steps.

Chapter 4 Six-Membered Carbocycles

243

MeC^OMe H Ì

OEt

ΌΗ

V-N...

30

31 EtO. CaC03 2 eq H 2 0 90%

32

In a related manner the ABE tricyclic core, 34, of manzamine A, 30, was reported. 18 Bradsher cycloaddition reaction of naphthyridium salt 35 with an elaborated enol ether afforded cycloadduct 36. Three steps were required to transform this compound into the advanced intermediate 37, a synthon for scaffold 34.

ΌΗ

30

}

244

Name Reactions for Carbocyclic Ring Formations

Building on their earlier work and in preparation for an enantioselective approach to manzamine A, 30, the Langlois group examined asymmetric variations on the Bradsher cycloaddition reaction. An initial report19 focused on using chiral (Z)-enol ether 38 with the previously used naphthyridinium salt 32. The cycloaddition reaction afforded 39 in good yield with 80% de. An alternative asymmetric Bradsher cycloaddition reaction reversed the sense of chirality, which resulted in the asymmetric center being Execution of the incorporated into the naphthyridinium salt 40.20 cycloaddition reaction with the elaborted enol ether 41 afforded cycloadduct 42. The overall yield and de were found to be similar to the previous example.

Chapter 4 Six-Membered Carbocycles

46

47

245

48

Sammes and co-workers21 reported studies on an intramolecular variation on the Bradsher cycloaddition reaction. However, the Franck group,22 publishing on the construction of benz[c,d]indole frameworks, reported an alternate structure for the product of their reaction. Intramolecular cycloaddition of the isoquinolinium salt 43 initially afforded adduci 44. This intermediate rapidly converted to 45, which gave 48 after acetylation. The Sammes group had assigned 47 to the final compound but the Franck group, based on NMR and crystal structure data from a related system, proposed the alternate structure 48. Thus this chemistry provided

246

Name Reactions for Carbocyclic Ring Formations

entry to the benz[c,d] indole system found in such natural products as lysergic acid diethylamide (LSD), 46. Bradsher reaction In parallel with the previous chemistry, the Bradsher reaction has also found utility in organic synthesis. This reaction has a narrower scope due to the polyaromatic ring framework that results from this cyclodehydration chemistry. Early reports from the Bradsher group highlighted new routes to anthracene derivatives 7.23 In the event, conversion of chloride 49 to ketone 6 was accomplished by treatment with cuprous cyanide followed by 1,2addition of a Grignard reagent. The cyclized product 7 was obtained by heating with hydrobromic acid. It was reported later that liquid sulfur dioxide as solvent was effective in facilitating the aromatic cyclodehydration.24

The Bradsher reaction was also found to be effective in the preparation of heterocyclic systems.25 For example, reaction of indole 50 with bromoacetone afforded indolo[2,3-a]acridinium salt 51.

50

51

Polycyclic aromatic hydrocarbons can easily be prepared using this methodology.26 Heating the diketone 52 with hydrobromic acid facilitated the double Bradsher reaction to generate hydrocarbon 53. This approach was more efficient than the Elbs reaction in that higher yields and no rearrangements were observed.

Chapter 4 Six-Membered Carbocycles

247

Application of the Bradsher reaction to the synthesis of natural products has also been reported. The first total synthesis of benzopyranobenzazepine alkaloid (±)-clavizepine, 54, was accomplished using a Bradsher reaction as the key step.27 Thus the tricyclic core of 54 was assembled by stannic chloride induced cyclization of 55 to afford a mixture of 56 and 57. If methanol-free dichloromethane was used in this cyclization, then 56 could be obtained as the sole product in 66% yield. Alternatively, 56 could be converted in 57 in excellent yield with PPTS. N— HO'

OMe

BnO

(X ^COoEt 1. SnCI4 OMe OMe

2. H20

CH2CI2

248

4.4.6

Name Reactions for Carbocyclic Ring Formations

Experimental

Bradsher cycloaddition reaction13 (

10-Dimethoxymethyl-3,4,4a,5,10,10a-hexahydro-2Ä-benzo[g]chromen-5yl)-(2,4-dinitro-phenyl)-amine60

\ H NHAr 60

To a solution of isoquinolinium chloride 23 (332 mg, 1 mmol) in 5 mL anhydrous MeOH was added powdered anhydrous calcium carbonate (600 mg, 6 mmol) and vinyl ether 58 (2 mmol). The reaction was stirred under N2 at 45 °C and judged completed by monitoring for the disappearance of 23 by TLC. The reaction mixture was filtered through Celite and washed with DCM, and the combined organics were concentrated to give the cycloadduct 59, which was used directly in the next step. The crude 59 from the previous step was diluted with anhydrous MeOH (10 mL), and Dowex-50x8-400 (250 mg) was added. The mixture

Chapter 4 Six-Membered Carbocycles

249

was stirred at room temperature for 24 h before filtering the resin. The resin was washed with DCM, the combined filtrates diluted with 150 mL of water, and the aqueous mixture extracted with DCM (3 x 30 mL). The combined extracts were washed once with satd NaHCCh (20 mL), dried (MgSC^), filtered, and chromatographed to afford 60 as a solid (88%). Bradsher reaction28 12-/M-Tolyl-benzo[a]anthracene 62 HBr AcOH

61

62

Ketone 61 (1 g) was dissolved in 15 mL 48% hydrobromic acid and 30 mL glacial acetic acid. The reaction mixture was heated in a sealed tube at 180 °C for 3 h before cooling to room temperature and extracting with benzene. The organic phase was washed with water, dried (CaCb), filtered, and concentrated. After purification by chromatography, 62 (0.9 g, 95%) was obtained as a colorless solid. 4.4.7 1. 2. 3. 4.

5. 6. 7.

8.

References [R] (a) Bradsher, C. K. Adv. Heterocyclic Chem. 1974, 16, 289. (b) Katritzky, A. R.; Dennis, N. Chem. Rev. 1989, 89, 827-861. [R] (a) Bradsher, C. K. Chem. Rev. 1946, 38, 447. (b) Bradsher, C. K. Chem. Rev. 1987, 87, 1277. Bradsher, C. K.; Solomons, T. W. G. J. Am. Chem. Soc. 1958, 80, 933-934. (a) Bachmann, W. E.; Deno, N. O. J. Am. Chem. Soc. 1949, 71, 3062. (b) Carboni, R. A.; Lindsey, R. V. J. Am. Chem. Soc. 1959, 81, 4342. (c) Sauer, J.; Wiest, H. Angew. Chem., Intl. Ed. 1962, 1, 269. (d) Sauer, J. Angew. Chemie Ml. Ed. 1967, 6, 16. Fields, D. L.; Regan, T. H.; Dignan, J. C. J. Org. Chem. 1968, 33, 390. [R] (e) Boger, D. L. Chem. Rev. 1986,56,781. For leading references see: [R] (a) Fleming, I. Frontier Orbitals and Organic Reactions. Wiley, 1976, pp 86-181. [R] (b) Anslyn, E. V.; Dougherty, D. A. Modern Physical Organic Chemistry, University Science Books 2006, pp 877-934. Bradsher, C. K.; Stone, J. A. J. Org. Chem. 1968, 33, 519. (a) Westerman, I. J.; Bradsher, C. K. J. Org. Chem. 1971, 36, 969. (b) Porter, N. A.; Westerman, I. J.; Wallis, T. G.; Bradsher, C. K. J. Am. Chem. Soc. 1974, 96, 5104. (c) Bradsher, C. K.; Carlson, G. L. B.; Porter, N. A.; Westerman, I. J.; Wallis, T. G. J. Org. Chem. 1978, 43, 822. (d) Bradsher, C. K.; Wallis, T. G.; Westerman, I. J. Porter, N. A. J. Am. Chem. Soc. 1977, 99, 2588. (e) Westerman, I. J.; Bradsher, C. K. J. Org. Chem. 1979, 44, 727. (f) Gupta, R. B.; Franck, R. C. J. Am. Chem. Soc. 1987, 709, 5393. Tamilmani, V.; Senthilnathan, D.; Venuvanalingam, P. J. Chem. Sci. 2008, 120, 225.

250 9. 10. 11. 12. 13. 14. 15. 16. 17. 18. 19. 20. 21. 22. 23. 24. 25. 26. 27. 28.

Name Reactions for Carbocyclic Ring Formations Falck, J. R.; Wittenberger, S. J.; Rajapaksa, D.; Mioskowski, C; Boubia, B. J. Chem. Soc, Perkin Trans. 1 1990, 413. [R] Fieser, L. F. Org. React. 1942, /, 129. See for example: (a) Bradsher, C. K.; Vingiello, F. A. J. Org. Chem. 1948, 13, 786. (b) Vingiello, F. A.; Spangler, M. O. L.; Bondurant, J. E. J. Org. Chem. 1960, 25, 2091. (c) Vingiello, F. A.; Thornton, J. R. J. Org. Chem. 1966, 31, 659. (a) Brice, L. K.; Katstra, R. D. J. Am. Chem. Soc. 1960, 82, 2669. (b) Lupes, M. E.; Lupes, S. A. L. Sci. Bull. Polytech. Instit. Bucharest Chem. Mat. Sci. 1990, 52, 53. (c) Lupes, M.; Lupes, S. Sci. Bull. Polytech. Instit. Bucharest Chem. Mat. Sci. 1990, 52, 77. a) Gupta, R. B.; Franck, R. W. J. Am. Chem. Soc. 1987, 109, 5393. b) Gupta, R. B.; Franck, R. W.; Onan, K. D.; Soil, C. E. J. Org. Chem. 1989, 54, 1097. Bolitt, V.; Mioskowski, C. J. Am. Chem. Soc. 1991,113, 6320. Yin, H.; Franck, R. W.; Chen, S.-L.; Quigley, G. J.; Todaro, L. J. Org. Chem. 1992, 57, 644. Nicolas, T. E.; Franck, R. W. J. Org. Chem. 1995, 60, 6904. Magnier, E.; Langlois, Y.; Merienne, C. Tetrahedron Lett. 1995, 36, 9475. Magnier, E.; Langlois, Y. Tetrahedron Lett. 1998, 39, 837. Sageot, O.; Monteux, D.; Langlois, Y. Tetrahedron Lett. 1996, 37, 7019. Urban, D.; Duval, E.; Langlois, Y. Tetrahedron Lett. 1996, 41, 9251. Gisby, G. P.; Sammes, P. G.; Watt, R. A. J. Chem. Soc, Perkin Trans. 1 1982, 249. Soil, C. E.; Franck, R. W. Heterocycles 2006, 70, 531. (a) Bradsher, C. K. J. Am. Chem. Soc. 1940, 62, 486. (b) Bradsher, C. K.; Smith, E. S. J. Am. Chem. Soc. 1943,65,451. Bradsher, C. K.; Sinclair, E. F. J. Org. Chem. 1957, 22, 79. Bradsher, C. K.; Litzinger, E. F., Jr. J. Org. Chem. 1964, 29, 79. Saraf, S. D.; Vingiello, F. A. Synthesis 1970, 655. Ishibashi, H.; Takagaki, K.; Imada, N.; Ikeda, M. Tetrahedron 1994, 50, 10215. Vingiello, F. A.; Borkovec, A. J. Am. Chem. Soc. 1955, 77, 4823.

Chapter 4 Six-Membered Carbocycles

4.5

251

Bradsher Reaction

Mukulesh Mondai and Nessan J. Kerrigan 4.5.1 Description

The acid-catalyzed cyclization of an acyl substituted diarylalkane 1 into a cyclic carbinol 2, followed by a 1,4-dehydration to produce anthracene derivative 3, is known as the Bradsher Reaction. ' 4.5.2 Historical Perspective Charles K. Bradsher2 (born in Petersburg, Virginia, in 1912) introduced this reaction in 1940.1 After obtaining a Ph.D. in 1933 from Harvard University and carrying out postdoctoral work at the University of Illinois, he joined the faculty at the department of chemistry, Duke University and achieved the rank of James B. Duke Professor in 1965. ^V-^CHO

OHC

4 H+ HoO

-H20 OHC 5

Ph

This particular reaction was observed for the first time by Bergmann during the hydrolysis of o-benzylbenzàldehyde in boiling hydrochloric acid, when he isolated a small amount of anthracene.3 A very similar reaction, perhaps the first case of aromatic cyclodehydration was reported by Zincke and Breuer in 1884, when they observed the formation of ßphenylnaphthalene from phenylacetaldehyde in boiling sulphuric acid (50%).4 Zincke postulated that aldol condensation of two molecules of

252

Name Reactions for Carbocyclic Ring Formations

phenylacetaldehyde followed by cyclodehydration furnished the naphthalene derivative 6. For many years applications of the Bradsher reaction were restricted due to its limited substrate scope and requirement for harsh reaction conditions.2'5 However, after the advancement of the arene oxide concept concerning the metabolism of poly cyclic aromatic hydrocarbons, synthesis of all the nuclear monohydroxylated derivatives of 7,12-dimethylbenz[a]anthracene (DMBA), diol epoxide metabolites of DMBA, and fluoro derivatives of DMBA was undertaken for carcinogenicity and mutagenicity determination studies.6-10 Interest in the Bradsher reaction has increased greatly as a consequence of the need to construct these polycyclic aromatic hydrocarbons. Development of fluoroanthracenylmethyl cinchonidine as an efficient phase-transfer catalyst for asymmetric glycine alkylation also expanded the scope of the Bradsher reaction.11'12 4.5.3 Mechanism Bradsher proposed that the mechanism initially involved reversible addition of the proton to the carbonyl group of 1 to form 7, followed by intramolecular Friedel-Crafts-type electrophilic attack on the aryl ring by the positively charged species in 8.2'5'13 15 Restoration of aromaticity through proton loss from 9 followed by acid-catalyzed 1,4-dehydration of carbinol 2 furnished the anthracene derivative 3.

Chapter 4 Six-Membered Carbocycles

253

A kinetics study by Brice and Katstra showed that during the cyclization of o-benzylbenzophenone 11 to 9-phenylanthracene 12 catalyzed by HBr in an acetic acid-water mixture, the reaction rate retards greatly as the mole fraction of water in the solvent increases.16 A dramatic increase in cyclization rate can be achieved if the HBr concentration is held constant but the mole ratio of acetic acid and water in the mixture is increased.

HBr AcOH/H20

To prove that the cyclization of o-benzylbenzophenone (11) did not proceed through an enolic intermediate, Bradsher and Smith refluxed the ketimine 13 with hydrobromic acid (48%) and observed that cyclization takes place despite the inability of the expected intermediate 14 to enolize. 9,10Dihydroanthracene derivative 15 was formed through concomitant reduction under the reaction conditions.17 Me Me

Me Me

Me Me

HBr

Substituents play an important role in the rate of cyclization of various o-benzylphenyl phenylketones. In the case of o-benzylphenyl phenyl ketones 1 (R = Ph, Ri = R.2 = H) in which the phenyl group has substituents, it was expected that electron-releasing substituents should stabilize the positive charge of the conjugate acid 8 and hence slow the cyclization to 2. On the other hand, the same substituents, by increasing the basicity of the ketone 1, should increase the concentration of 8 at equilibrium.

254

Name Reactions for Carbocyclic Ring Formations

HO R [2]

R 3

Bradsher and Vingiello observed that when the substituent on the benzoyl group was in the para position, the rate of cyclization for methyl, hydrogen, chlorine or bromine substituents was the same, within experimental error of each other.18 However, in the case of the fluorine substituent, a significant lowering of rate was observed. In a similar experiment, Vingiello's group observed that the rate of cyclization increased slightly for the same halogen substituents when the position is changed from para to meta.i9 In the case of halogens in the para position, the +M (Mesomeric) effect in addition to the -I (Inductive) effect is responsible for a slight lowering of the rate of cyclization compared to the me/a-substituted case where only -I effect is in operation. However, when the trifluoromethyl group is in the para position, with the strong - I effect and electron withdrawing hyperconjugation effect, a higher rate of cyclization than that in the meta position, where only -I effect is operative, was observed. Since the +M effect of the methyl group is of hyperconjugative origin and its magnitude is smaller in comparison to that of a halogen, the rate of cyclization for para- and weta-methyl substituents is almost the same. Hence the electronic effects on the positive nature of the conjugate acid 8 are more important in determining the overall reaction rate than those affecting the acid-base equilibrium.

Chapter 4 Six-Membered Carbocycles

255

Rates of cychzation of some o-benzylphenyl aryl ketones 1 K,(h _ 1 )xl0 - 2 Entry No. R R i = R 2 = R3 1 /?-CH3C6H4 H 4.2 H 4.2 2 /?-BrC6H4 3 p-C\C6ÌU H 4.1 H 2.8 4 p-FC 6 H 4 H 9.3 5 p-C¥3 H 4.4 6 C6H5 H 4.4 7 w-CH3C6H4 H 5.0 8 m-BrC6H4 H 5.3 9 m-ClC6H4 H 5.3 10 m-FC6H4 H 6.4 11 w-CF3 Analogous or^o-substituents on the benzoyl group show comparatively large variations in rates of cychzation. All ori/zo-substituted compounds cyclize more slowly than the unsubstituted 2-benzylbenzophenone. The variation appears to be due to the increasing steric requirements of the substituents in the expected order Br > Cl > F. In this case, the steric bulk of the substituent inhibits the attack of the electropositive carbon atom on the nucleophilic benzene ring. Rates of cychzation of some o-benzylphenylbenzophenone 1 at 150 °C K,(h _1 )xl0" 2 Entry No. R Ri == R2 == R3 C6H5 H 55 1 H 9.5 2 0-CH3C6H4 o-BrC6H4 H 3.3 3 o-ClCeH4 H 4 6.9 0-FC6H4 H 38.6 5 The rate of cychzation of o-(l-phenylethyl)phenyl alkyl ketone 1 (R = alkyl, Ri = Me, R2 = H) decreases steadily from methyl to «-butyl and then Λ 1

remains constant within the limit of experimental error. The major factor in the large decrease in rate of cychzation with increasing chain length is most likely steric interactions. In contrast to the small rate change observed by modifying the electronic environment of the carbonyl group of o-benzylphenyl aryl ketones, a large change in the rate of cychzation can be made by modifying the availability of electrons at the ortho position of the nucleophilic benzene. The introduction of a methyl group at the 3 position of the benzyl ring of 1 (R = Ph, Ri = R2 = H, R3 = W-CH3) makes the cychzation 55 times faster compared to the unsubstituted ring, while replacing the methyl group with a

256

Name Reactions for Carbocyclic Ring Formations

trifluoromethyl group (R = Ph, Ri = R2 = H, R3 = m-C¥{) makes the cyclization impossible even after 10 days under reflux.22 Rates of cyclization of some o-(l-phenylethyl)phenyl alkyl ketone 1 R2 = R3 K,(min _1 )xl0" 2 Entry No. R Ri H 4.6 1 Me Me H 1.8 2 Ethyl Me H 0.99 3 «-Propyl Me H 0.35 4 «-Butyl Me H 0.36 5 w-Pentyl Me H 0.36 6 «-Hexyl Me Rates of cyclization of some 1 Entry No. R R,= R2 C6H5 H 1 C6H5 H 2 C6H5 H 3 C6H5 H 4 H 5 C6H5

R3 H 0-CH3 m-CH3 m-CF3 /7-CH3

K,(h~')xl0" 2 4.4 15.4 200 No reaction 13.8

The introduction of either a methyl or phenyl group at Ri in 1 (R = Ph, R2 = H) increases the rate of cyclization.18 In both cases, the enhancement of cyclization rate may be due to an slight increase in electron density at the ortho position at which cyclization takes place. Although it should be noted that when R\ = Ph, there are four such positions available for cyclization with a corresponding increase in probability of the reaction. Rates of cyclization Entry No. R 1 C6H5 2 C6H5 3

C6XI5

of some o-benzylphenyl ketones 1 K, (h ] )xl0~ 2 R, R2 = R3 H H 4.4 CH3 H 13 C6H5

H

13

In summary, the rate of cyclization of o-benzylbenzophenones depends on several factors, the most important of which appear to be (1) the steric nature of R (and perhaps also Ri), (2) the effective positive character of the carbonyl carbon of the conjugate acid, (3) electron density at the ortho position of the nucleophilic benzene ring, and (4) the number of such positions available.

Chapter 4 Six-Membered Carbocycles

4.5.4

257

Variations and Improvements

The requirement of relatively harsh conditions for the Bradsher cyclodehydration (generally under refluxing hydrobromic acid-acetic acid mixture conditions due to high activation energy barriers) has restricted the use of the Bradsher reaction in the synthesis of complex highly functionalized organic molecules. However there have been considerable efforts devoted to performing the Bradsher cyclodehydration under milder conditions. Bradsher and Sinclair attempted an aromatic cyclodehydration at lower temperature for heat-sensitive substrates and reported the cyclization of obenzylbenzophenone (11) to 9-phenylanthracene (12) in the presence of a vigorously stirred fine suspension of phosphorous pentoxide in liquid sulfur dioxide at-10 °C with a moderate yield (53%) of 12 being obtained.24

P205 Liquid SO? -10°C 53%

In an innovation, Newman applied polyphosphoric acid (PPA) in place of the usual mixture of hydrobromic acid and acetic acid.25 PPA had been used earlier in the aromatic cyclodehydration for preparation of phenanthrene derivatives.26,27 Newman applied PPA under thermal conditions for the aromatic cyclodehydration of an unactivated ketone 16 to afford 17, an aromatic carcinogen, in moderate yield. In contrast, the use of a mixture of hydrobromic and acetic acids failed to give the cyclized product.

PPA

60°C

20 min 43%

Vingiello and Schlechter described the Bradsher cyclodehydration of o-benzylphenyl ketone containing a strongly basic group in the presence of either phenyl acid phosphate or benzenesulfonic acid.28 4-Benzylphenyl pyridyl ketone (18) underwent cyclization in the presence of phenyl acid

258

Name Reactions for Carbocyclic Ring Formations

phosphate at 190 °C to yield 9-(4-pyridyl)anthracene (19) quantitatively, whereas the same cyclization in the presence of benzenesulfonic acid at 150 °C afforded 19 in 65% yield.8

Conditions

Entry No. 1 2

Conditions Phenyl acid phosphate, 190 °C, 5 h Benzenesulfonic acid, 150 °C, 5 h

Yield (%) Quant. 65

Vingiello and Thornton examined the aromatic cyclodehydration of 2-(3-methylbenzyl)phenyl-2-naphthyl ketone (20) to 2-methyl-10-(2naphthyl)anthracene (21) in the presence of either alumina at 250 °C or liquid hydrogen fluoride at room temperature.29 Results indicate that the use of liquid hydrogen fluoride constitutes very mild conditions and only sterically and electronically favorable substrates give the desired product in good yield, but in those cases liquid hydrogen fluoride was found to be higher yielding than the alumina-catalyzed cyclization.

Entry No. 1 2

Conditions Yield (%) Alumina, 250 °C, 2.5 h 50 Liquid Hydrogen Fluoride, it, until acid 72 evaporates

The use of zinc chloride in a refluxing mixture of acetic acid and acetic anhydride allow the Bradsher cyclodehydration to be extended to aromatic acids.8'9'30 Newman and co-workers reported the cyclization of 2(4-methoxybenzyl)-l-napthoic acid (22), on treatment with zinc chloride in

Chapter 4 Six-Membered Carbocycles

259

boiling acetic acid and acetic anhydride, into 12-acetoxy-10-methoxybenz[a]anthracene (23) in very good yield.8 ZnCI2 OMe

OMe

AcOH/Ac20 Reflux 90 min 92%

Yamato and co-workers introduced dichloromethyl methyl ether in the presence of titanium tetrachloride as a reagent for one-pot formylation followed by in situ Bradsher cyclization. In this way anthracene regioisomers 25 and 26 were obtained from diarylmethane 24 in good yield. The initially formed anthracene derivative presumably reacts with excess dichloromethyl methyl ether to yield 9- or 10-formylanthracene derivative 25 or 26.

26 (25%)

Neckers and co-workers have synthesized two new representatives of pentacyclic [a,d]-fused ladder-type aromatic sulfur containing materials— namely, thieno[3,2-/:4,5-/]bis[l]benzothiophene (28-syn) and thieno[2,3yi5,4-/]bis[ 1 ]benzothiophene (30-anti)—using Amberlyst-15-mediated Bradsher cyclodehydration under refluxing conditions.32 CHO OHC

Amberlyst-15 benzene * reflux S Dean-Stark trap 36 h 46%

260

Name Reactions for Carbocyclic Ring Formations Amberlyst-15 PhH, reflux CHO^s OHC 29

4.5.5

Dean-Stark trap 36 h, 24%

Synthetic Utility

Until the mid-1970s, the Bradsher cyclization was not applied to biologically interesting targets due to its substrate limitations and the general requirement of drastic conditions. After the advancement of the arene oxide concept concerning the metabolism of polycyclic aromatic hydrocarbons, Newman and co-workers synthesized 1-, 2-, 3-, 4-, 6-, 9-, and 10-hydroxy-7,12dimethylbenz[a]anthracene (DMBA, 31-37) using the Bradsher reaction, to determine the carcinogenicity and mutagenicity of each compound.

R6

Me

R5

31, Ri = OH; R2, R3, R4, R5, Re and R 7 = H 32, R2 = OH; R b R3, R4, R5, Re and R7 = H 33, R3 = OH; Ru R2, R4, R5, Re and R7 = H 34, R4 = OH; Ri, R2, R3, R5, RÓ and R7 = H 35, R5 = OH; R,, R2, R3, R4, Re and R7 = H 36, Re = OH; Ri, R2, R3, R4, R5 and R7 = H 37, R7 = OH; R h R2, R3, R4, R5, and Re = H Newman and co-workers reported the carcinogenic activity of 7methylbenz[a]anthracene (7-MBA) 38, 12-methylbenz[a]anthracene (12MBA) 39 and 7,12-dimethylbenz[a]anthracene (DMBA) 40 in 1972.33 The planar hydrocarbon 38 possesses high carcinogenic activity, nonplanar analogue 39 has low carcinogenic activity, while another nonplanar analogue 40 is the most potent carcinogenic polycyclic aromatic hydrocarbon (PAH) commonly employed in carcinogenesis research.34"36 DMBA-induced rat mammary carcinoma is the standard laboratory animal model in the study of human breast cancer.35

Chapter 4 Six-Membered Carbocycles

261

Diol epoxide metabolites of DMBA such as trans-3,4-dihydroxy-antil,2-epoxy-l,2,3,4-tetrahydro-DMBA (41) or iraws-3,4-dihydroxy-sy«-l,2epoxy-l,2,3,4-tetrahydro-DMBA (42) has been implicated as the principle active form of DMBA which binds covalently to DNA in vivo.36 The intermediacy of 41 and 42 was further supported by the development of methods for their synthesis by using the Bradsher cyclization for the construction of the DMBA moiety, coupled with studies of their mutagenicity, tumorigenicity and DNA binding. '

The carcinogenic activity of polycyclic aromatic hydrocarbons is often strongly affected by the substitution of fluorine in suitable In some cases, the inhibition activity caused by fluorine positions.38'3 substitution is due to interference with activation by the P-450 microsomal Conversely, enzymes to reactive PAH diol epoxide metabolites.40 enhancement of activity by introduction of fluorine into other molecular regions may be considered primarily a consequence of restriction of oxidative metabolism. One of the most thoroughly investigated examples of these effects is the highly potent PAH carcinogen 7,12-dimethylbenz[a]anthracene (DMBA) (40). While the 1-, 2-, 4- and 5-fluoro derivatives of DMBA (43-46) exhibit markedly reduced activity relative to the parent hydrocarbon 40, substitution of fluorine in the 8-, 9-, and 11-position (47, 48 and 50) results in no significant loss of activity.41'42 Tumor-initiating studies on male rats have shown, however, that the carcinogenic activity of 10-fluoro DMBA 49 is greater than that of DMBA.43 Similar effects were seen for the 7- and 12-monomethyl analogs, 7-MBA 38 and 12-MBA 39.44

262

Name Reactions for Carbocyclic Ring Formations

43, Ri = F; R2, R,, R5, Rg, R9, Rio and Ri = H 44, R2 = F; Ri, R4, R5, Re, R9, Rio and Ri = H 45, R4 = F; Ri, R3, R5, Rg, R9, Rio and R, = H 46, R5 = F; Ri, R2, R4, Rg, R9, Rio and R, = H 47, R8 = F; Ri, R2, R4, R5, R9, Rio and Ri = H 48, R9 = F; Ri, R2, R4, R5, Rg, Rio and R, = H 49, R,0 = F; Ru R2, R4, R5, Rg, R9 and R, = H 50, R„ = F; R,, R2, R4, R5, Rg, R 9 and R 10 = H To verify the possibility that the presence of a fluorine atom in the 9or 10-positions of the DMBA diol epoxide isomers might remotely influence the reactivity of the epoxide function, Harvey synthesized trans-3,4dihydrodiol of 9- and 10-fluoro-DMBA, 7-MBA and 12-MBA.10 These fluoro-dihydrodiols are putative proximate carcinogenic metabolites that undergo activation by the P-450 microsomal enzymes to carcinogenic antiand syn-àioì epoxide metabolites that bind to nucleic acids in vivo. The synthesis of several anti-dio\ epoxide derivatives using the Bradsher cyclization was also reported.

a: R = CH3, R' = H; b: R = H, R' = CH3, c: R

CH3

Morreal and co-workers reported the synthesis of an antiestrogenic compound, 3,9-diol-7,12-DMBA 55 using the Bradsher reaction.45 Antiestrogens are known to antagonize the growth of estrogen-dependent human breast cancer.46 Molecular modeling of 55 showed that its phenolic hydroxyl groups are equivalent to the hydroxyl groups of the natural estrogen 17/?-estradiol. At a dose of 0.5 mg 55, a decrease in the percentage of rats in estrus from 78% to 44% was observed. This decrease is identical to that caused by 0.5 mg nafoxidine.

Chapter 4 Six-Membered Carbocycles

263

Pentacene (56), a member of the acene series of linear polycyclic aromatic hydrocarbons, is a fundamental component of organic field-effect transistors (OFET).47 In an attempt to rectify its shortcomings such as poor solubility, limited stability in solution and unfavourable stacking in the solid state, Neckers and co-workers have synthesized two new representatives of pentacyclic [a,c/]-fused ladder type aromatic sulphur-containing materials. Thieno[3,2-/4,5-/]bis[l]benzothiophene (2%-syn) and thieno[2,3-/5,4-/]bis[l]benzothiophene (30-anti) were prepared using an Amberlyst-15-catalyzed Bradsher cyclodehydration under refluxing conditions, and their optical and electrochemical properties were reported.

30-Anti

Ar-

Andrus and co-workers developed fluoroanthracenylmethyl cinchonidine 57 as an efficient phase-transfer catalyst, and it was explored The fluoroanthracenylmethyl for asymmetric glycine alkylation.11'1 precursor was synthesized from an aryloxazolidinone and aldehyde using the Bradsher reaction in the key step. This cinchonidine catalyst promotes

264

Name Reactions for Carbocyclic Ring Formations

highly selective glycine alkylation under mild conditions. The placement of l,8-difluoro-anthracenyl-10-methyl on the quinuclidine nitrogen accentuates steric interactions and provides a larger region for nonbonded interactions, leading to a significant increase in selectivity. Electronegative fluorine substituents contribute to the overall electron deficiency of the positively charged catalyst, enhancing the degree of ion pairing with the enolate. This effect facilitates both phase transfer and enhances nonbonded interactions leading to improved selectivity. 4.5.6

Experimental

Thermal acid-catalyzed bradsher reaction: 9-phenylanthracene (12)1

A stirring mixture of 11 (2.06 g, 7.57 mmol) in a mixture of acetic acid (20 mL) and 34% hydrobromic acid (20 mL) was refluxed for 4 days. Upon cooling, the product solidified as fluorescent plates which, after recrystallization from ethanol, yielded 1.44 g (75%) 12 as a crystalline solid. Phosphorus pentoxide-mediated bradsher reaction at low temperature: 9-phenylanthracene (12)24

To a stirring mixture of 11 (500 mg, 1.84 mmol) in liquid sulfur dioxide (50 mL), was added phosphorus pentoxide (5.0 g, 17.61 mmol), and the reaction mixure was stirred for several hours at -10 °C. Then carbon tetrachloride (20 mL) was added, and the mixture was allowed to stand until the ice first formed had melted and most of the sulfur dioxide had evaporated. The carbon tetrachloride layer was separated from water, and the aqueous layer was extracted with more carbon tetrachloride. The combined organics were washed with water thrice and dried over calcium chloride. Removal of

Chapter 4 Six-Membered Carbocycles

265

solvent under reduced pressure followed by recrystallization from ethanol furnished 247 mg (53%) 12 as a crystalline solid. Amberlyst-catalyzed thermal Bradsher /]bis|l|benzothiophene (30-anti)32 S

/S.

O V t ) fCHO u n Nx«s / OHC nur

29

reaction: thieno[2,3-/:5,4-

Amberlyst-15 PhH reto

'

Dean-Stark trap 36 h, 24%

To a stirring solution of 29 (1.63 g, 4.90 mmol) in dry benzene, amberlyst-15 (0.5 g) was added and the reaction mixture was refluxed for 36 h. Water was removed by means of a Dean-Stark trap. After cooling, dichloromethane was added to dissolve the precipitate and the mixture was filtered through a cotton plug. The filtrate was washed with saturated aqueous NH4CI solution and dried over anhydrous MgSC>4. Evaporation of the solvent followed by silica gel column Chromatographie purification using hexane as eluent yielded a pale white solid. Recrystallization from CHCI3 furnished 0.35 g (24%) anii-30 as pale white crystals. 4.5.7 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18. 19. 20.

References Bradsher, C. K. J. Am. Chem. Soc. 1940, 62, 486^88. [R] Bradsher, C. K. Chem. Rev. 1987, 87, 1277-1297. Bergmann, E. J. Org. Chem. 1939, 4, 1-13. Zincke, T.; Breuer, A. Justus Liebigs Ann. Chem. 1884,226,23-60. [R] Bradsher, C. K. Chem. Rev. 1946, 38, 447^199. [R] Jerina, D. M.; Daly, J. W. Drug Metabolism from Microbe to Man Taylor & Francis, London, 1976, 13. Jerina, D. M; Yagi, H.; Daly, J. W. Heterocycles 1973,1, 267-326. Newman, M. S.; Khanna, J. M.; Kanakarajan, K.; Kumar, S. J. Org. Chem. 1978, 43, 25532557. Lee, H.; Harvey, R. G. J. Org. Chem. 1986, 57, 3502-3507. Harvey, R. G.; Cortez C. Tetrahedron 1997, 53, 7101-7118. [R] (a) Maruoka, K.; Ooi, T. Chem. Rev. 2003, 103, 3013-3028. [R] (b) Kacprzak, K.; Gawronski, J. Synthesis 2001, 961-998. [R] (c) O'Donnell, M. J.; Ace. Chem. Res. 2004, 37, 506-517. [R] (d) Lygo, B.; Andrews, B. I. Ace. Chem. Res. 2004, 37, 518-526. Andrus, M. B.; Ye, Z.; Zhang, J. Tetrahedron Lett. 2005, 46, 3839-3842. Berliner, E. J. Am. Chem. Soc. 1942, 64, 2894-2898. Bradsher, C. K.; Smith, E. S. J. Am. Chem. Soc. 1943, 65, 854-857. [R] Smith, M. B.; March, J. in March's Advanced Organic Chemistry, 5thed., Wiley, New York, 2001, 720. Brice, L. K.; Katstra, R. D. J. Am. Chem. Soc. 1960, 82, 2669-2670. Bradsher, C. K.; Smith, E. S. J. Am. Chem. Soc. 1943, 65, 1643-1645. Bradsher, C. K.; Vingiello, F. A. J. Am. Chem. Soc. 1949, 71, 1434-1436. Vingiello, F. A.; Van Oot, J. G.; Hannabass, H. H. J. Am. Chem. Soc. 1952, 74, 4546-4548. Vingiello, F. A.; Spangler, M. O. L.; Bondurant, J. E. J. Org. Chem. 1960, 25, 2091-2094.

266 21. 22. 23. 24. 25. 26. 27. 28. 29. 30. 31. 32. 33. 34. 35. 36.

37. 38. 39. 40. 41. 42. 43. 44. 45. 46. 47.

Name Reactions for Carbocyclic Ring Formations Berliner, E. J. Am. Chem. Soc. 1944, 66, 533-535. Vingiello, F. A.; Van Oot, J. G. J. Am. Chem. Soc. 1951, 73, 5070-5072. Henson, P. D.; Vingiello, F. A. J. Org. Chem. 1967, 32, 3205-3207. Bradsher, C. K.; Sinclair, E. F. J. Org. Chem. 1957, 22, 79-81. Newman, M. S.; MacDowell, D.; Swaminathan, S. J. Org. Chem. 1959, 24, 509-512. Hauser, C. R.; Murray, J. G. J. Am. Chem. Soc. 1955, 77, 3858-3860. Bradsher, C. K.; Jackson, W. J., Jr. J. Am. Chem. Soc. 1952, 74,4880^1883. Vingiello, F. A.; Schlechter, M. M. J. Org. Chem. 1963, 28, 2448-2450. Vingiello, F. A.; Thornton, J. R. J. Org. Chem. 1966, 31, 659-663. Harvey, R. G.; Cortez, C; Sugiyama, T.; Ito, Y.; Sawyer, T. W.; DiGiovanni, J. J. Med. Chem. 1988,57, 154-149. Yamato, T.; Sakaue, N.; Shinoda, N.; Matsuo, K. J. Chem. Soc, Perkin Trans. 1, 1997, 1193-1199. Wex, B.; Kaafarani, B. R.; Kirschbaum, K.; Neckers, D. C. J. Org. Chem. 2005, 70, 45024505. Newman, M. S.; Cunico, R. F. J. Med Chem. 1972, 75, 323-325. Jones, D. W.; Sowden, J. M. Cancer Biochem. Biophys. 1976, 281-288. Welsch, C. W. Cancer Res. 1985, 45, 3415-3443. (a) Moschel, R. C; Baird, W. M.; Dipple, A. Biochem. Biophys. Res. Commun. 1977, 76, 1092-1098. (b) Bigger, C. A. H; Sawicki, J. T.; Blake, D, M.; Raymond, L. G.; Dipple, A. Cancer Res. 1983, 43, 5647-5651. (c) Dipple, A.; Pigott, M.; Moschel, R. C; Constantino, N. Cancer Res. 1983, 43, 4132^4135 and references cited therein. (a) Slaga, T. J.; Gleason, G. L.; DiGiovanni, J.;Sukumaran, K. B.; Harvey, R. G. Cancer Res. 1979, 39, 1934-1936. (b) Sawicki, J. T.; Moschel, R. C; Dipple, A. Cancer Res. 1983, 43, 3212-3218. [R] (a) Harvey, R. G. Polycyclic Aromatic Hydrocarbons; Chemistry and Carcinogenicity, Cambridge University Press, Cambridge, UK, 1991. (b) Harvey, R. G. Polycyclic Aromatic Hydrocarbons, Wiley-VCH, New York, 1997. [R] Dipple, A.; Moschel, R. C; Bigger, C. A. H. In Chemical Carcinogenesis, 2nd Edition; C. E. Searle, Ed.; ACS Monograph, 182; American Chemical Society, Washington, D.C., , 1984, pp. 41-163. [R] Harvey, R. G.; Geacintov, N. E. Ace. Chem. Res. 1988, 21, 66-73. (a) Harvey, R. G.; Dunne, F. B. Nature 1978, 273, 566-568. (b) Huberman, E.; Slaga, T. J. Cancer Res. 1979, 39, 411^114. (e) DiGiovanni, J.; Diamond, L.; Singer, J. M.; Daniel, F. B.; Witiak, D. T.; Slaga, T. J. Carcinogenesis 1982, 3, 651-655. DiGiovanni, J.; Decina, P. C; Diamond, L. Carcinogenesis 1983, 4, 1045-1049. Newman, M. S.; Veeraraghavan, S. J. Org. Chem. 1983, 48, 32346-32348. Diamond, L.; Cherian, K.; Harvey, R. G.; DiGiovanni, J. Mutai. Res. 1984,136, 65-72. Morreal, C. E.; Sinha, D. K.; Schneider, S. L. Bronstein, R. E.; Dawidzik, J. J. Med. Chem. 1982, 25, 323-326. (a) Dao, T. L.; Suderland, J. J. Nati. Cancer Inst. 1959, 23, 567—585. (b) Dao, T. L. Cancer Res. 1962, 22, 973-981. [R] (c) Dao, T. L. Prog. Exp. Tumor Res. 1964, 5, 157-216. (a) Sakamoto, Y.; Suzuki, T.; Kobayashi, M.; Gao, Y.; Fukai, Y.; Inoue, Y.; Sato, F.; Tokito, S. J. Am. Chem. Soc. 2004, 126, 8138-8140. [R] (b) Volkel, A. R.; Street, R. A.; Knipp, D. Phys. Rev. 2002, B66, 195336-195343. (c) Kwon, O.; Coropceanu, V.; Gruhn, N. E.; Durivage, J. C; Laquindanum, J. G.; Katz, H. E.; Cornil, J.; Bredas, J. L. J. Chem. Phys. 2004,720,8186-8194.

Chapter 4 Six-Membered Carbocycles

4.6

267

Darzens Synthesis of Tetralin Derivatives

Ewa Krawczyk and Roman Dembinski 4.6.1 Description Cyclization of 2-benzylpent-4-enoic acid (α-benzyl-oc-allylacetic acid) and related compounds 1 to corresponding 1,2,3,4-tetrahydronaphthalene (tetralin) derivatives 2, catalyzed by a strong acid, has been called Darzens synthesis of tetralin derivatives. The reaction formally falls into the category of a cycloisomerization reaction of alkenyl-substituted arenes.

z

ΠΓ r ^ Ι Γ

HA

)

ΠΓΊ

.z

Me

1

2

4.6.2 Historical Perspective Georges Darzens (at the École Polytechnique in Paris, France) in 1926 described the conversion of 2-benzylpent-4-enoic acid 3 into 4-methyltetrahydronaphthalene-2-carboxylic acid 4 that has proceeded under the influence of concentrated sulfuric acid.1 Subsequent dehydrogenation and decarboxylation yielded a naphthalene derivative. This work was followed by a series of extended reports.2-5 The outcome of Darzens et al. (Levy, Heinz) sequence of works in this area has been reviewed.6 C02H

C02H 78% H2SQ4 <45°C

4.6.3 Mechanism Although in the past a few mechanistic schemes have been drawn,7 currently the plausible reaction mechanism may be described as the acid-initiated formation of an intermediate carbenium ion followed by SEAr, and thus falls into the broad category of the Friedel-Crafts alkylation. This may be one of

268

Name Reactions for Carbocyclic Ring Formations

the reasons that the name of the reaction is not often seen in current literature. A plausible mechanistic outline that involves a carbenium ion is illustrated below. Initial protonation of alkene 1 generates a more favorable secondary cationic intermediate 5, which interacts with an aromatic ring, forming the σ-complex 6. Deprotonation furnishes the desired product 2. Migration of the C=C bond via 5 to an internal alkene (not illustrated) may contribute to the mechanistic pathway, also leading predominantly to the product 2. H+ + HC" Me

-mr H

-H+

Me

In the case of the Darzens reaction involving 2-benzylpent-4-enoic acid or related compounds, the process is accompanied by the formation of the γ-lactone 7 that was isolated, and later confirmed to also produce tetrahydronaphthalenecarboxylic acid 4, when treated with 65% sulfuric acid at 120 °c. 8 " 10 Formation of δ-lactone 8 was also observed.8

4.6.4

Variations and Improvements

Initially, the cyclization reaction of 2-benzylpent-4-enoic acid 4 was carried out using concentrated sulfuric acid as both the catalyst and the solvent at a temperature below 45 °C.1 Further, the repetoire of Bronsted acids (used at ambient or higher temperature) has been expanded to include anhydrous hydrogen fluoride (0 °C), n trifluoroacetic acid (toluene, 70 °C or acetic acid, 70 °C), 12,13 ' polyphosphoric acid (xylenes, reflux), ' and anhydrous pyridinium poly(hydrogen fluoride)14 (room temperature). Darzens et al. also used readily available malonic acid ester derivatives as substrates in reaction with sulfuric acid. 2 ^' 16-19 More recent studies and the NMR evidence demonstrated that for the cyclization of 2methylallyl malonate 9 the use of anhydrous hydrogen fluoride is advantageous and leads to dimethyl tetrahydronaphthalene derivative 10.11

Chapter 4 Six-Membered Carbocycles

269

When malonate 9 is treated with polyphosphoric acid at room temperature, formation of lactone 11 is observed, similar to the Darzens procedure with the use of sulfuric acid. _1 The structure of lactone is being retained during subsequent hydrolysis and decarboxylation of the exocyclic ester group; followed up treatment with anhydrous hydrogen fluoride gives dimethyl tetrahydronaphthalene carboxylic acid 12. Hydrolysis and decarboxylation of 10 under standard conditions gives the same product 12." C02Et C02Et MeO

HF 0 °C, 85%

MeO

Me polyphosphoric acid 0 °C, 73% EtO,C O ^ ΜβΛ/le

MeO

1.KOH, EtOH, Δ 2. HCI aq 3. 175 °C, - C 0 2 4.HF,rt,45%

C02H MeO

11

Similar reactions involving an allylic fragment proceed with formation of the SN2' type products. Indium(III) salts (InCl3 predominantly investigated)20 have been found to be effective Lewis acids to catalyze conversion of 13 at room temperature in the presence of molecular sieves. ' The cyclization is accompanied by elimination of hydrogen bromide, leading to the vinyl derivatives of tetrahydronaphthalene 14 and tolerates electronwithdrawing groups. C02Et c

°2Et

Br 13

lnCI3(10mol%), 4 A MS CH2CI2, rt, 93% 14

If the aromatic ring is unsymmetrically substituted, the reaction may lead to a mixture of products. Thus w-methoxybenzyl amine derivative 15 is transformed into vinyl tetrahydroisoquinolines 16 (major) and 17 (minor). Regioisomers 16 and 17 were formed by para and ortho cyclization,

Name Reactions for Carbocyclic Ring Formations

270

respectively, with reference to the methoxy group.21 NTs Br

MeO

MeO

NTs

lnCI3(10mol%), 4 A MS CH2CI2, rt, 98%

*

Ts = p-MeC6H4S02

15

Reaction leading to analogous vinyl tetrahydronaphthalenes with elimination of acetoxy group has also been reported and the role of the substituents at the allylic acetate moiety investigated.12'13 The presence of alkyl/aryl substituents raise the reaction rate. Best efficiency has been accomplished with the aid of trifluoroacetic acid/acetic acid 3 : 1 ratio. The reaction has been extended to the conversion of cyclohexene ring-containing optically active substrate 18 into optically active tricyclic skeleton 19 in excellent yield and stereoselectivity. C02Me C02Me

CF3C02H/AcOH(3:1) rt, 99%, 98% ee

C02Me C02Me fr

02CPh 19

18

Vinyl substituted tetrahydronaphthalenes, analogs to 14, can currently be obtained in high yield by employing a gold catalyst for the cyclization of 4-allenyl arenes.2 Although the scope of the reaction is limited to electronrich arenes, acetals are tolerated, and compound 20 leads predominantly to /?ara-cyclized product 21 in high yield.

< //'

// 20

C02Me C02Me

C02Me o C02Me (PhO)3PAuCI (3 mol%) ^ ( AgSbF6 (5 mol%) O CH2CI2, rt, 93% 21

Chapter 4 Six-Membered Carbocycles

4.6.5

271

Synthetic Utility

Influence of the substituents has been investigated. In general, activating substituents at the aryl ring of 4 promote cyclization. If the carboylic group is attached to the benzyl position, the reaction proceeds slower.4 The presence of isopropyl as a substituent attached to the C=C hampers the cyclization reaction;17 detailed analysis of scope and limitations is provided in the review. Darzens reported that compounds of type 4 can be dehydrogenated to l-methyl-3-naphthoic acid 22 with the use of sulfur or selenium at elevated Subsequent decarboxylation using lime yielded 1temperature.1' '4 methylnaphthalen 23. This sequence of reaction can be carried out in one pot.2'4 Through a series of reactions the methyl naphthoic acid 22 can be converted to 4-methyl-2-naphthol 24, and further, with the aid of Vilsmeyer formylation to alkyl naphthofuran 25. 23 C02H

1/8 S8 (2 equiv)

^195-200 °C, vacuum

lime, Δ vacuum

22

23

24

25

In an analogous way, Darzens and Levy have synthesized isopropylmethylnaphthalene (eudaline) 26, which contains a dehydrogenated sesquiterpene "eudesmol" motif.3 The reaction is applicable for the synthesis of methyl derivatives of phenanthrene such as 27.

Me

Me

26, eudaline

Name Reactions for Carbocyclic Ring Formations

272

The reaction tolerates the presence of a phenyl group at the carbon atom that forms the bond with the aryl ring well, and can be stopped before decarboxylation or proceeds further to monocarboxylic acids derivatives of tetralin. As an example, cyclization of malonate 28 at room temperature with the use of anyhydrous hydrogen fluoride gives dicarboxylate 29. u The anhydrous pyridinium poly(hydrogen fluoride) is more efficient in the same reaction.14 Compound 29 is obtained with almost quantitative yield with purity sufficient to use a crude product for the follow-up synthetic transformations, which lead to derivatives of l-phenyl-3-aminotetralins 30 that exhibit potential for the treatment of Parkinson disease.1 '15 C02Et C02Et (HF)x · pyridine rt, 100% 28

29

30

The reaction has been extended to synthesis of tetralone derivatives.15'24,25 Thus treatement of 31 with polyphosphoric acid leads to 15 the substituted 3-tetralone 32,,:> which can be also converted to l-phenyl-3aminotetraline 33 providing a complementary synthetic route to that one for 30 illustrated above.

polyphosphoric acid * xylenes, reflux quantitative

31 4.6.6

32

33

Experimental

Darzens intramolecular cyclization reaction of 2-benzylpent-4-enoic acid (3) with the use of sulfuric acid: 4-methyl-l,2,3,4-tetrahydronaphthalene-2-carboxylic acid (4) ' Fine powder of compound 3 (1 equiv) and concentrated sulfuric acid (78%, 2.5 mass equiv) were mixed. Precautions were taken to avoid a temperature increase above 45 °C. The mixture was left at ambient temperature for 5 days to allow homogenizing and solidifying. After this time, water was

Chapter 4 Six-Membered Carbocycles

273

added, and the mixture was neutralized with sodium bicarbonate (12%) until the sodium salt of the acid 4 was obtained. Next, the addition of the excess of hydrochloric acid resulted in the formation of a solid. Crystallization from acetic acid (80%) gave 4 as a white powder (50%, m.p. 121 °C), which can be distilled without decomposition giving a colorless fraction (203-204 °C/20 mm Hg). Intramolecular cyclization reaction of malonate ester (28) with the use of anhydrous hydrogen fluoride11 or anhydrous pyridinium poly-(hydrogen fluoride:14 diethyl l,2,3,4-tetrahydro-4-methyl-4-phenylna-phthalene2,2-dicarboxylate (29) Compound 28 (109.8 g, 0.3 mol) and 400 g anhydrous hydrogen fluoride in a 1-L polyethylene bottle were kept in an ice bath for 12 h. The hydrogen fluoride was then allowed to evaporate spontaneously during 24 h of stirring at room temperature. Water was then added, and the organic material was extracted several times with ether. The ether extracts were combined and washed with a 10% sodium bicarbonate solution until the solution remained slightly basic; then they were washed with a saturated solution of sodium chloride and dried over anhydrous sodium sulfate. The ether was then evaporated, and vacuum distillation (200 °C/0.3 mm Hg) gave a very viscous white oil (98.8 g, 90%). The dicarboxylate crystallized out on standing. Crystallization from alcohol gave 29 as white crystals (100%). Compound 28 (27.2 g, 0.074 mol) was placed in a 500-mL poly(propylene) bottle, and 75 g of pyridinium poly(hydrogen fluoride) was added. The mixture was then stirred overnight at room temperature. The excess hydrogen fluoride was neutralized by addition of water followed by aqueous NaOH (20%, 200 mL) and the organic material was extracted into ether. The combined ether extracts were dried (NaiSCU) and evaporated in vacuo to give 29 as a light orange oil (27.3 g, 100%). Gas chromatography and H NMR analyses indicated essentially pure product, which was used in the next step without further purification. Intramolecular cyclization reaction of malonate ester (13) with the use of indium(III) chloride: diethyl 6-fluoro-4-vinyl-3,4-dihydronaph-thalene2,2(l#)-dicarboxylate (14)21 Compound 13 (0.040 g, 0.10 mmol) and dichloromethane (2 mL, 0.05 M) were placed in a small screw-cap scintillation vial equipped with a magnetic stirbar. Powdered 4 Ä molecular sieves (0.050 g) and indium(III) chloride (0.0022 g, 0.010 mmol) were added, and the reaction was allowed to stir at room temperature. Upon completion of the reaction (usually 16 h), the

274

Name Reactions for Carbocyclic Ring Formations

mixture was loaded onto a silica gel column directly and eluted using hexane-ethyl acetate (10 : 1) to afford 14 (93%). 4.6.7 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18. 19. 20. 21. 22. 23. 24. 25. 26.

References Darzens, G. Compi. Rend. 1926, 183, 748-750. Darzens, G.; Heinz, A. Compi. Rend. 1927, 184, 33-35. Darzens, G.; Levy, A. Compi. Rend. 1932,194, 2056-2059. Darzens, G.; Levy, A. Compi. Rend. 1934,199, 1131-1133. Darzens, G.; Levy, A. Compi. Rend. 1934,199, 1426-1428. [R] Linstead, R. P. Ann. Rep. Prog. Chem. 1936, 33, 312-341. [R] Bergmann, E. Chem. Rev. 1941,29, 529-551. Darzens, G.; Levy, A. Compi. Rend. 1935, 200, 469^t71. Darzens, G. Compi. Rend. 1930,190, 1305-1306. Darzens, G. Compi. Rend. 1930, 190, 1562-1564. Kandeel, E. M.; Anderson, L. J.; Block, J. H.; White, A. I.; Martin, A, R. J. Pharm. Sci. 1972,67,1231-1234. Ma, S.; Zhang, J. Tetrahedron Lett. 2002, 43, 3435-3438. Ma, S.; Zhang, J. Tetrahedron 2003, 59, 6273-6283. Wyrick, S. D.; Booth, R. G.; Myers, A. M.; Owens, C. E.; Bucholtz, E. C; Hooper, P. C; Kula, N. S.; Baldessarini, R. J.; Mailman, R. B. J. Med. Chem. 1995, 38, 3857-3864. Wyrick, S. D.; Booth, R. G.; Myers, A. M.; Owens, C. E.; Kula, N. S.; Baldessarini, R. J.; McPhail, A. T.; Mailman, R. B. J. Med. Chem. 1993, 36, 2542-2551. Darzens, G. Compt. Rend. 1926,183, 1110-1112. Darzens, G.; Levy, A. Compt. Rend. 1930,191, 1455-1457. Darzens, G.; Levy, A. Compt. Rend. 1935, 200, 2187-2189. Darzens, G.; Levy, A. Compt. Rend. 1936, 202, 427-428. Cook, G. R.; Hayashi, R. Org. Lett. 2006, 8, 1045-1048. Hayashi, R.; Cook, G. R. Org. Lett. 2007, 9, 1311-1314. Tarselli, M. A.; Gagné, M. R. J. Org. Chem. 2008, 73, 2439-2441. Chatterjea, J. N.; Lai, S.; Jha, U.; Carnduff, J. Ind. J. Chem., Sect. B: Org. Chem. Incl. Med. Chem. 1981, 20, 264-267. [R] Silveira, C. C; Braga, A. L.; Kaufman, T. S.; Lenardào, E. J. Tetrahedron 2004, 60, 8295-8328. [R] Fieser, L. F.; Fieser, M. In Current Topics in Organic Chemistry, Reinhold, New York, 1963,p548. We are grateful to Edith Chopin, Krzysztof Owsianik, and Maria Zabtocka for the translation of the original Darzens articles.

Chapter 4 Six-Membered Carbocycles

4.7

275

Diels-Alder Reaction

Kevin M. Shea Description

4.7.1

The Diels-Alder reaction is the most important synthetic method for the preparation of six-membered rings. Combination of a conjugated diene (1) with a separate alkene (2) or alkyne (the dienophile) yields a substituted cyclohexene (3). This cycloaddition reaction is often highly regio-selective and stereo-selective, yielding predictable configurations at the four potential new stereocenters formed in the reaction. In the most popular variations, an electron-rich diene is combined with an electron-poor dienophile, and the reaction is promoted by heat or addition of a Lewis acid. Inverse electron demand Diels-Alder reactions involving the combination of an electron-poor diene with an electron-rich dienophile is also possible. The scope of the Diels-Alder reaction is broad with respect to the substituents on the diene and dienophile. In addition, it readily occurs intermolecularly1 and intramolecularly, and incorporation of heteroatoms in both the diene and dienophile4 is common (the hetero Diels-Alder reaction). A variety of chiral Lewis acid catalysts enable highly enantioselective reactions for many substrates.5

R

4

R5

•f^R6 R 3 - K/R' R 1

4.7.2

7

8

R \ ^R \^'» + R 9 A R 1 0

2

2

Δ or Lewis acid

R >-

RE R6

4

ÌT

R3"

OR?8 P'R J-R 9

R< R1 3

Historical Perspective

Kurt Alder obtained his Ph.D. in 1926 at the University of Kiel, Germany, under the direction of Otto Paul Hermann Diels. After obtaining his degree, Alder continued conducting research in Diels's lab on reactions of unsaturated compounds.6 Diels and Alder published their seminal paper describing the reaction of 1,3-butadiene (4) with acrolein (5) to yield substituted cyclohexene 6 in 1928.7 Although similar reactions had appeared previously in the literature, Diels and Alder's investigations greatly expanded the scope of the "diene reaction" (later renamed in their honor).8'9

276

Name Reactions for Carbocyclic Ring Formations

In 1936, Alder left the University of Kiel to pursue research efforts in industry. He continued to study the diene reaction, focusing on the stereochemical course of the transformation. Consequently, the preference for endo products in the reaction is generally referred to as the Alder Endo Rule. Diels and Alder's achievements in advancing the utility of this powerful reaction were recognized with the Nobel Prize in chemistry in 1950.6 4.7.3

Mechanism

A complete picture of the Diels-Alder mechanism involves explaining the regioselectivity and stereoselectivity of the reaction as well as understanding the molecular orbital description for the transformation. Reactions are impossible for dienes that cannot adopt cisoid conformations (see 4 for an example of a cisoid diene) for steric or other reasons. Cyclic dienes with imposed cisoid geometry are among the most reactive dienes.5 An arrowpushing mechanism can be easily drawn using three curved arrows to demonstrate the reorganization of three π bonds into one new π bond and two new σ bonds; however, this simplistic analysis does not help explain why the Diels-Alder reaction occurs thermally but not photochemically.

The mechanism of the Diels-Alder reaction was first fully described by Woodward and Hoffmann using their orbital symmetry rules for cycloadditions. The Woodward-Hoffmann rules state that the Diels-Alder reaction is a thermal [4π8 + 2 π8] cycloaddition involving overlap of the diene's highest occupied molecular orbital (HOMO) ψ 2 with the dienophile's lowest unoccupied molecular orbital (LUMO) ψ 2 . In the case of an inverse electron demand Diels-Alder reaction, the dienophile's HOMO ψ 1 combines with the diene's LUMO ψ 3 . 10

Chapter 4 Six-Membered Carbocycles

277

Diene ψ3 + Dienophile ψ1

Diene ψ2 + Dienophile ψ2

Inverse Electron Demand Reaction

Standard Reaction

This is generally a concerted synchronous process with both new bonds forming simultaneously. Combinations of some highly polar substrates undergo concerted asynchronous reactions in which the two new σ bonds are formed at different rates.5 In some rare cases, the reaction proceeds in a stepwise fashion with the absence of expected stereoselectivity. Orfanopoulos reported an example of a stepwise hetero Diels-Alder reaction in 2009. n Experimental results and theoretical analyses have enabled rational predictions for the regiochemical preferences in Diels-Alder reactions.12 Known as the ortho, para rule, the strongest electron donating group on the diene ends up either ortho (1,2) or para (1,4) to the strongest electronwithdrawing group on the dienophile in the final cyclohexene product. For example, combination of isoprene (7) with methyl acrylate (8) yields mostly para product 9, while reaction of 8 with 1-methylbutadiene 11 furnishes ortho cyclohexene 12 as the major product. As shown in these cases, formation of mixtures is common under thermal conditions.13

OCH-

Δ

OCH3

OCH·,

+

10 Minor

OCH3 +

OCH·,

11

These results are explained by analyzing the frontier molecular orbital (FMO) coefficients for the orbitais involved in the reaction. Combination of the largest coefficient on the diene with the largest coefficient on the dienophile accurately predicts the regiochemical outcome of the reaction.5 For reaction partners lacking complicated substitution patterns, the ortho,

Name Reactions for Carbocyclic Ring Formations

278

para rule can be derived by drawing resonance structures for the diene and dienophile and connecting the most negative carbon on the diene with the most positive carbon on the dienophile.1 The stereochemical outcome of the reaction is also well understood. Due to the concerted nature of the process, it is stereospecific with respect to the diene and dienophile. Substituents that are eis on the dienophile are eis in the product and likewise for /raws-substituents. Substitution at carbons 1 and 4 of the diene yield stereocenters in the product. Groups in these positions that pointing "out" on the diene end up on one face of the product, while groups pointing "in" are on the other face of the cyclohexene.1

Stereospecific with respect to the dienophile

Mrans

trans

O^OCH 3

cr"0CH3

Rin, Rout

C0 2 CH 3 C0 2 CH 3

Rin

Stereospecific with respect to the diene

Rout

The Alder endo rule enables predictions of product structures that combine stereocenters generated from both the diene and dienophile. Based on Alder's pioneering studies, he demonstrated that endo products are favored over exo products.15 The easiest way to determine the endo product is that the withdrawing group on the dienophile ends up eis to groups pointing out on the diene in the cyclohexene product.

Endo product Mrans out

The preference for endo products is rationalized by interaction of the π orbital of the withdrawing group with the p orbital at C-2 of the diene π system. This secondary orbital interaction overcomes the steric preference for the exo product.1416

Chapter 4 Six-Membered Carbocycles

4.7.4

279

Variations and Improvements

The most important variations and improvements since Diels and Alder's studies include promoting the reaction with something other than heat, incorporating heteroatoms in both the diene and dienophile, reversing the electronics to combine electron rich dienophiles with electron poor dienes, developing asymmetric versions of the reaction, and covalently connecting the diene and dienophile to yield intramolecular reactions. The reverse of the Diels-Alder reaction, the retro Diels-Alder, is also highly useful in organic synthesis.17 Lewis Acids and Related Promoters The most important advance in Diels-Alder methodology was the discovery that reactions could be effectively promoted by addition of a variety of Lewis acids.1 This eliminated the need to thermally promote the reaction and often afforded the cyclohexene products in higher yield and better regioselectivity and stereoselectivity. As explained by the Woodward-Hoffmann rules for cycloadditions, Lewis acids bind to the electron-withdrawing group on the dienophile and lower the energy of the dienophile LUMO. This decreased diene HOMO-dienophile LUMO gap decreases the activation energy for the reaction. All of the common Lewis acids, TiCU, SnC^, SnCU, ZnCt, ZnBr2, BF3, EtAlCL., EÌ2A1C1, and lanthanide complexes, have found successful application in Diels-Alder reactions.19 Most contemporary studies of Lewis acids are focused on the development of chiral catalysts for asymmetric Diels-Alder reactions (vide infra). Perlmutter reported a recent example of the superiority of Lewis acid catalysis versus thermal conditions. Thermal reactions between naphthaquinones like 14 and dienes similar to 15 lead to aromatization of the cycloadducts. Perlmutter isolated the target Diels-Alder product 16 in nearly quantitative yield using catalytic BF3.20

280

Name Reactions for Carbocyclic Ring Formations

H«

BF 3 · OEt 2 1

Ή

CH 2 CI 2 , -30 °C 99%

15

16

Transition metals are also useful catalysts for the title cycloaddition, and copper catalysts have proven especially effective.21 In an example from Furstner's lab, unactivated alkyne 17 undergoes an intramolecular DielsAlder reaction catalyzed by copper thiophene 2-carboxylate (CuTC) to provide bicycle 18 in 95% yield.22 EtO,C CO,Et cat. CuTC

C0 2 Et " C0 2 Et

CH2CI2 rt, 6 h

17

95%

A variety of other reaction conditions promote the Diels-Alder 5 14 23 24 reaction ' including high pressure, ultrasound, electron transfer, polar ionic liquids, supramolecular scaffolds, enzymes, solvents, 28 29 ribozymes, Bronsted acids and bases, and π-basic transition metal 30 complexes. Hetero Diels-Alder Reactions Diels-Alder reactions are excellent methods for the production of a plethora of six-membered ring-containing heterocycles. A variety of heterodienes3 and heterodienophiles readily participate in the reaction with, not surprising, oxygen and nitrogen the most popular heteroatoms for inclusion. Recent reviews highlight the use of imino-containing dienes,31 imino dienophiles,32 carbon-phosphorous π bonds, the synthesis of spiroketals,34 the synthesis of carbohydrate-containing molecular scaffolds,35 and ring opening of hetero Diels-Alder products.3 Hetero-Diels-Alder reactions play important roles in inverse electron demand, asymmetric, and intramolecular Diels-Alder reactions and will appear prominently in those sections. Several recent examples highlight the utility of the hetero-DielsAlder reaction. Combination of enone 19 with dienophile 20 in the presence

Chapter 4 Six-Mem ber ed Carbocycles

281

of a europium catalyst and high pressure yields cycloadduct 21, which was ultimately converted into a substituted glycoside 37 NPht

NPht 15mol%Eu(fod) 3

OBn

1

CH2CI2, 13kBar, 50 °C, 4 d

FaC

19

20

OBn

50%

Miller illustrated the use of a nitroso dienophile in his synthesis of Diels-Alder product 24 from ergosterol (22) and nitroso 23. Subsequent cleavage of the N - 0 bond in 24 furnished an ergosterol derivative with significant anticancer activity.

CH2CI2, 0 °C 92%

Inverse Electron Demand Diels-Alder Reactions As already mentioned, electron-poor dienes react with electron-rich dienophiles in what are known as inverse electron demand Diels-Alder reactions.5,14 The most common versions of this type of transformation are hetero Diels-Alder reactions, though carbocyclic examples do exist.

282

Name Reactions for Carbocyclic Ring Formations

Yamomoto reported an interesting carbocyclic inverse electron demand Diels-Alder reaction between tropone (25) and ketene diethyl acetal (26) catalyzed by tris(pentafluoro)phenylborane. Under these conditions, Diels-Alder product 27 is formed almost exclusively, while most other catalysts (including BF3 and BPI13) favor sole production of the [8 + 2] cycloadduct 28. Yamamoto also described the development of an asymmetric version of this Diels-Alder reaction.39 10mol%B(C6F5)3 CH2CI2, 0 °C 25

26

>99:1

/C20Et + OEt 27

fy

.O^OEt

0E{

28

Nelson disclosed a powerful three-component Diels-Alder/alkylation reaction sequence for the synthesis of several nitrogen-containing heterocycles. For example, treatment of enamine 29 with titanium tetrachloride yields electron poor imminium ion diene 30 that reacts with unactivated cyclohexene to furnish imminium ion cycloadduct 31. Introduction of allyltrimethylsilane into the reaction mixture leads to alkylation of the reactive imminium ion and production of perhydroisoquinoline 32 in 59% overall yield. Due to the lack of secondary orbital interactions, this inverse electron demand Diels-Alder reaction is exo1 . . . . . . 4 0 selective to minimize stenc interactions.

"\P 31

Taylor used an inverse electron demand Diels-Alder/retro-DielsAlder/aromatization cascade for the synthesis of bicyclic pyridines. Beginning with 1,2,4 triazine 33, reaction with electron-rich dienophile 34 yields cycloadduct 35, which eliminates N2 on a retro Diels-Alder reaction.

Chapter 4 Six-Membered Carbocycles

283

Loss of pyrrolidine from 36 provides the target pyridine product 37 in 80% yield. 41 Moody employed a similar Diels-Alder reaction of 1,2,4-triazines as part of a three-step conversion of hydrazides into substituted pyridines. C02Et

toluene, μ\Λ/ 120°C, 1 h PhS

PhS

80%

34 Diels-Alder

aromatization

Et02C retro Diels-Alder -N, PhS

PhS

35

Inverse electron demand Diels-Alder reactions also have applications in biological systems. Fox reported that electron poor tetrazine diene 39 successfully forms a bioconjugate with the protein thioredoxin modified to contain a frvms-cyclooctene (38). In an example of this Diels-Alder reaction in the absence of thioredoxin, tetrazine 39 combines with trans-cyclooctene to yield cycloadduct 40 in quantitative yield. Like the synthesis of 37 described above, this reaction proceeds via a Diels-Alder/retro Diels-Alder cascade with elimination of N2. The reaction works well in organic solvents, water, and cellular media with 41 generated as the final product in protic solvents.43

H ^

Diels-Alder then retro N Diels-Alder

H

1

N

N 38

40 min., rt low cone. 100%

284

Name Reactions for Carbocyclic Ring Formations

Asymmetric Diels-Alder Reactions The recent explosion in the development of asymmetric strategies for organic synthesis has fostered investigations into the discovery of methods for enantioselective and diastereoselective Diels-Alder reactions.44-^ Some early forays into this field focused on the use of chiral auxiliaries49 covalently attached to one of the reaction partners; however, nearly all recent investigations have centered on developing chiral catalysts. The multitude of new catalysts spans the range of Lewis acids and Brensted acids and bases29 as well as metal-based21 and organic molecules. One of the most effective classes of asymmetric Diels-Alder catalysts is the family of chiral oxazaborolidines originally developed by Corey. In a recent example from Corey's lab, combining cyclopentadiene (42) with quinone 43 in the presence of catalyst 44 furnishes cycloadduct 45 in 99% yield and 99% ee.50 Yamamoto used a similar catalyst for enantioselective Diels-Alder reactions of α,β-unsaturated acetylenic ketones,51 and PaddonRow and Houk reported a computational investigation into the reactivity of oxazaborolidine catalysts 52 H Ph 4 mol% BroAl

CH2CI2, -78 °C, 30 min. 99%, 99% ee

Metal bis(oxazoline) catalysts are also highly efficient at promoting asymmetric Diels-Alder reactions. Ishira developed a highly selective copper bis(oxazoline) catalyst for use in standard intermolecular Diels-Alder reactions.53 Arrayas and Carretero used a nickel bis(oxazoline) catalyst in inverse electron demand hetero Diels-Alder reactions of 1-azadienes for the production of functionalized piperidines.54 Sibi studied a variety of metal bis(oxazoline) catalysts in reactions between cyclopentadiene and pyrazolidinone dienophiles and determined that copper and palladium catalysts were most efficient.55 Sibi applied a copper bis(oxazoline) catalyst in a kinetic resolution experiment in which one enantiomer of dienophile 46 reacts selectively with cyclopentadiene to yield cycloadduct 48 and 98% ee

Chapter 4 Six-Membered Carbocycles

285

of unreacted 47. Base-promoted amide cleavage furnished the separate 56 pyrazolidinones 49 and 50.

P

o

o

5 mol% Cu(OTf)2

5.5 mol% Y7

/-Pr 98% ee selectivity factor = 34 LiOPMB

48 O' LiOPMB

In addition to metal-based catalysts, organocatalysts are also selective promoters of asymmetric Diels-Alder reactions.57 Several groups reported the use of cinchona alkaloid catalysts in standard Diels-Alder reactions. Deng combined 2-pyrones with α,β-unsaturated ketones,58 while Bernardi and Ricci focused on the reactions of vinylindoles with quinones and maleimides.59 Lectka reported enantioselective inverse electron demand hetero Diels-Alder reactions of ketene enolates and o-benzoquininone diimides catalyzed by a combination of benzoylquinidine and zinc triflate. For example, subjecting diimide 51 to the standard reaction conditions yields cycloadduct 52 as a single stereoisomer, which can be easily converted to

Name Reactions for Carbocyclic Ring Formations

286

diamine 53. The proposed mechanism for this Diels-Alder reaction is a stepwise process.60

a;

ΟγΡη

j Cr^Ph

51

OyPh

ci 10 mol% catalyst

ι Ρ γ ^ γ ^ LÌA'H4t ιτ^γ Ν γ' ^ΑΝΛ0 THF k A N J

10mol%Zn(OTf)2 Hunig's base THF > "78 °c 76%, >99% ee

J cAph

mn%

H

53

52

Using a relatively simple chiral secondary amine catalyst (56), Chen prepared a series of highly functionalized enantiomerically pure piperidines via inverse electron demand hetero Diels-Alder reactions. For example, amine catalyst 56 reacts with unsaturated aldehyde 55 to furnish a dienamine that functions as the electron-rich dienophile for combination with electronpoor 1 -azadiene 54 and provides piperidine 57 in high yield and enantiomeric excess.61 NTs

CHO v

C02Et

54 cat. 56

55 OSiMe3 Ph Ph

room temp 95%, 99% ee © Mes

0.5 mol% Γ

H

CI 58

C02CH3

Ph 59

VjCI

'Ό 60_ 1.5 equiv NEt3 EtOAc, rt 88%, > 20:1 cfr, 99% ee

cA^-pn /i

^>C02CH3 61

Chapter 4 Six-Membered Carbocycles

287

Bode demonstrated the effectiveness of N-heterocyclic carbenes as catalysts for inverse electron demand hetero Diels-Alder reactions involving both azadienes and oxodienes. In the oxodiene case, reaction of enones with oc-chloroaldehydes affords substituted dihydropyranones. In one example, addition of catalyst 60 to chloroaldehyde 58 followed by elimination of HC1 yields the electron-rich dienophile that readily combines with oxodiene 59 to selectively furnish cycloadduct 61. Another important class of enantioselective catalysts for Diels-Alder reactions are ΒΓΝΑΡ-based catalysts. These are employed either as Bronsted acid or transition-metal complexes. Yamamoto reported that acyclic siloxydienes combine with azopyradines in the presence of a silver BINAP catalyst to yield the target nitrogen-containing heterocycles in high yield and selectivity.63 Akiyama and Terada each separately studied ΒΓΝΑΡsubstituted phosphoric acid derivatives as Bronsted acid catalysts for hetero Diels-Alder reactions. Terada demonstrated the ability of these catalysts to promote the stereoselective combination of siloxydienes with glyoxylate to yield substituted dihydropyrans.64 In another example of an inverse electron demand hetero Diels-Alder reaction, Akiyama selectively generated tetrahydroisoquinolines by combining aldimines and vinyl ethers in the presence of chiral phosphoric acid catalyst 64. For example, aldimine 62 reacts with ethyl vinyl ether to afford target 65 in high yield as virtually a single stereoisomer.65

10mol% EtO N^Ph 62

+

^ 63

EtO ^

-Ar

toluene, -10 °C

89%, 99:1 dr, 95% ee

64 ^r"N""Ph I H OH 65

Intramolecular Diels-Alder Reactions The intramolecular Diels-Alder reaction is most frequently used in natural product total synthesis, and numerous examples will be described in the synthetic utility section. As with the intermolecular variant, intramolecular reactions are highly regioselective and stereoselective and participate in hetero, inverse electron demand, and asymmetric Diels-Alder reactions. One report from 2008 describes the investigation of an intramolecular hetero Diels-Alder reaction in ionic liquids.66

288

Name Reactions for Carbocyclic Ring Formations

Roush has a long-standing interest in the intramolecular Diels-Alder reaction, and he recently reported the use of siloxacyclopentenes as dienophiles in intramolecular Diels-Alder reactions. Prolonged heating of 66 produces intramolecular adduct 67 that can be easily converted to diol 68 via a Fleming-Tamao oxidation. This reaction sequence is notable for the selective production of a racemic mixture of the isomer shown (no other r diastereomers observed), and diol 68 is the formal product of an intramolecular Diels-Alder reaction with an enol dienophile. S ? KF, H 2 0 2 , KHC03 190 °C 7 days

Prr'-I H Me2Si O 67

72%

Prr-I H HO OH 68

Van de Weghe disclosed an intramolecular hetero Diels-Alder reaction with an imino diene as part of a synthetic strategy for the synthesis of uncialamycin. In the key Diels-Alder reaction, boron trifluoride promotes the cycloaddition followed by DDQ-mediated oxidation to afford aromatic product 70.68

BF·,· OEt, DDQ CH2CI2, rt, 1 h 72% OCH-, 69 4.7.5

Synthetic Utility

The Diels-Alder reaction is a versatile tool for the synthesis of a plethora of target molecules. This section will focus on some of the most common applications, including the use of interesting dienes and dienophiles, tandem/cascade processes, and total syntheses.5'1

Chapter 4 Six-Membered Carbocycles

289

Interesting Dienophiles Benzyne is a fascinating dienophile that Lautens recently employed in a diastereoslective synthesis of benzo-fused heterobicycles. Treatment of 72 with fluoride yields benzyne, which readily combines with its diene partner, the functionalized pyrrole 71, to yield target cycloadduct 73 in high yield and selectivity.69

NBoc

TfO

72

Boc

CsF, CH3CN, rt 96%, >19:1 dr 71

73

Allenes are another unusual class of synthetically useful dienophiles. Jung demonstrated that intramolecular Diels-Alder reactions of optically active allenic ketones yield substituted oxa-bridged octalones. For example, optically pure aliene 74 undergoes a facile cycloaddition to yield a single diastereomer of target 75. ™

Me2AICI -78 to -20 °C 88% 74

75

Danishefsky's interest in the development of synthetically useful Diels-Alder reaction methodology has recently extended to two different dienophiles. First, he studied the reactivity of enyne dienophiles to show that ynones react preferentially to enones. Substituted styrene 78 is the exclusive product on intermolecular Diels-Alder reaction of diene 76 with dienophile 77 followed by a retro Diels-Alder reaction (to generate 2-methylpropene) and two desilylations.71

290

Name Reactions for Carbocyclic Ring Formations C02Me

OSiMe3

C02Me

neat 120 °C C02Me 98% 77

Me3SiO 76

C02Me 78

Danishefsky also investigated the development of a trans Diels-Alder reaction in seeming violation of the inherent stereoselectivity of the reaction mechanism. The key to this process was the use of 1-nitrocyclohexene (80) as the dienophile. After a standard intermolecular Diels-Alder reaction with diene 79, eis cycloadduct 81 could be transformed preferentially into transfused product 82 upon radical denitration and enol ether hydrolysis 72 OMe

toluene 130 °C, 36 h

OoN

90%

TBSO' 79

MeO 1

TBSO

80 1)nBu3SnH,AIBN benzene, reflux 2 h H trans:cis = 8:1 82

2)HF CH3CN, rt 10 min. 53% for 2 steps

Carreno reported a similar strategy for the production of trans DielsAlder products. Instead of nitro-substituted dienophiles, he employed quinones substituted with boronic acids. Reaction of boronic acid dienophile 82 with diene 83 yields the expected cycloadduct as an unstable intermediate that is selectively protonated and then loses boron to yield the ultimate trans fused product 84.7 B(OH)2

CH2CI2, rt OTBS 83

30 min. 95%

OTBS 84

Chapter 4 Six-Membered Carbocycles

291

Interesting Dienes Due to their increased reactivity, cyclic dienes are very useful in the DielsAlder reaction. Several groups have recently reported interesting applications of functionalized cyclopentadienes. Pearson demonstrated that cyclopentadienones react with aryl alkynes to yield polysubstituted biaryl compounds. Highly functionalized biaryl 87 is available in high yield on reaction of cyclopentadienone 85 and electron-poor aryl alkyne 86. The mechanism of this reaction includes extrusion of carbon monoxide to yield the pentasubstituted benzene after the initial cycloaddition.774 SiMe3 1

x \

HO JÒ= °

II

+

Ί

VSl0 7

°°C'48h 88%

SiMe3 85

toluene

11

HO

HO.

86

Gleason developed a method to generate stable 5-substituted cyclopentadienes for use as reactive Diels-Alder dienes. Unlike most similarly substituted cyclopendienes, compound 88 does not undergo rapid [l,5]-sigmatropic shifts and reacts quickly enough in Diels-Alder reactions to provide good yields of the desired target compounds. For example, diene 88 combines with dienophile 89 to afford endo product 90 in 79% yield. Gleason demonstrated the utility of this diene in a synthetic approach to the E

ing of palau'amine.75

0 TBSO^

7

88

CH2CI2 rt, 30 min.

OTBS

0 89

79%

TBS

V

TBSO"^

i4 90

0

One of the most popular acyclic dienes in the Diels-Alder reaction is Danishefsky's diene (91) and numerous research groups have developed chiral catalysts for the reaction of this diene with a variety of dienophiles.76 For example, Nishida reported that Yb(III)-BINAMIDE complexes catalyze the asymmetric reaction of Danishefsky's diene with electron-deficient alkenes. In one case, diene 91 reacts with dienophile 92 to selectively provide a functionalized cyclohexene that, on hydrolysis, affords the desired chiral cyclohexenone 93 in high yield and high eeV

Name Reactions for Carbocyclic Ring Formations

292

TBSCX ν ^

ίΐ χν ~~Ν' /χ ο

^

2) TFA

y OMe

91

1)10mol%chiral Yb complex 94ο/θι 94o/o

e e

92

93

The other recent examples of asymmetric syntheses involving Danishefsky's diene focused on hetero Diels-Alder reactions. Shibasaki and Feng separately reported asymmetric reactions with carbonyl dienophiles. Shibasaki demonstrated successful asymmetric reactions of ketones using a chiral Cu(I)-Walphos catalyst.78 Feng used a chiral jV,iV'-dioxide/In(OTf)3 catalyst in asymmetric cycloaddition reactions of aldehydes.79 Imine dienophiles are also amenable to asymmetric Diels-Alder reactions with Danishefsky's diene. Wulff reported enantioselective reactions using a VAPOL-B(OPh)3 catalyst system,80 while Snapper and Hoveyda disclosed silver-catalyzed enantioselective aza Diels-Alder reactions.81 Welker developed a useful synthetic strategy involving silyl substituted dienes.82 He can easily prepare large quantities of 2-siliconsubstituted 1,3-dienes that readily participate in Diels-Alder reactions followed by cross-coupling reactions to yield aryl substituted cyclohexenes. Diene 94 smoothly combines with ./V-phenylmaleimide (95) to furnish a silyl cyclohexene that undergoes Hiyama cross-coupling with iodobenzene to provide 96.83 N(CH 2 CH 2 0) 3 Si\ T;; ^

J{

+ f|

O

N-Ph

1)rt, THF, 30 min., 98% 2) cat. Pd(ll), PPh3 TBAF, Phi, 84%

-

f|

O / \ ^

T ^ N-Ph

P h ^ ^ ^ ^ 96 O

Sherburn reported a robust synthesis of the fascinating diene [4]dendralene (97) and its behavior in Diels-Alder reactions with Nmethylmaleimide (89, NMM). Dendralene 97 is available in one step from chloroprene and combines with three equivalents of an TV-methylmaleimidemethyl aluminium dichloride complex to provide a diastereomeric mixture of 98 after three Diels-Alder reactions.84

Chapter 4 Six-Membered Carbocycles

293

3 equiv NMM '2MeAICI2 complex, toluene 1

-78 °C to rt 97

71%

Reactions with conjugated enynes as dienes in Diels-Alder reactions yield cyclohexadiene or benzene products on reaction with alkene or alkyne dienophiles, respectively. These reactions proceed via a stepwise mechanism to avoid formation of a cyclic aliene and are referred to as dehydro-DielsAlder reactions.85 In 2008, Barluenga and Aguilar demonstrated that gold catalysts promote intermolecular hetero-dehydro-Diels-Alder reactions between dienynes and nitriles. Dienyne 99 combines with phenylnitrile (100) to afford substituted pyridine 101.86 OCH·,

H3C02C

N

5 mol% AuCIPEt3/AgSbF6

Ph

DCE, 85 °C

100

67%

101

Tandem and Cascade Reactions The Diels-Alder reaction has a rich history of applications in tandem and 5,14,87,i cascade processes. Many of the transformations already discussed have a cascade-like nature since processes like retro-Diels-Alder reactions and aromatization reactions often occur after the initial Diels-Alder step. Clearly, the triple Diels-Alder reaction of [4]dendralene described by Sherburn (97—>98) involves a beautiful cascade of cycloaddition reactions. In 2006, Wood described a tandem aromatic oxidation/Diels-Alder reaction for the synthesis of the carbocyclic core of bacchopetiolone. Oxidation of substituted phenol 102 with bis(trifluoroacetoxy)-iodobenzene (BTIB) provides bicycle 103 that dimerizes via a Diels-Alder reaction to yield poly cyclic 104, which is two decarbonylations away from the target natural product.89

294

Name Reactions for Carbocyclic Ring Formations

Et 3 NH0

BTIB 60% 2 steps

CH3CN

103

Tietze reported a domino-Knoevenagel-hetero-Diels-Alder reaction involving a three-component reaction between an a-nitroketone, formaldehyde, and an alkyl vinyl ether. In one example, a Knoevenagel condensation between ketone 105 and formaldehyde (106) yields electronpoor hetero-diene 108 that undergoes an inverse electron demand DielsAlder reaction with ethyl vinyl ether to furnish dihydropyran 109. Tietze subsequently converted 109 into the deoxysugar (+)-forosamin.

+

J "A

+

<^OEt

Ο,Ν

106

105

CH2CI2 3 h 80 °C

1

37%

107 OEt

Ο,Ν

108

Ο,Ν

109

Enders described a fascinating organocatalytic one-pot asymmetric synthesis of tricyclic compounds using a triple-cascade/Diels-Alder reaction sequence. Combination of dieneal 110 with enal 111 and nitro alkene 112 in the presence of a chiral amine catalyst results in a Michael/Michael/aldol condensation sequence to yield cycloaddition precursor 113. Cooling the reaction mixture and addition of a Lewis acid promotes the desired intramolecular Diels-Alder reaction to selectively afford the highly functionalized tricyclic target 114.91

Chapter 4 Six-Membered Carbocycles

295

114

Applications in Total Syntheses The true scope and limitations of any reaction are discovered when applied in challenging total syntheses. In this arena, the Diels-Alder reaction has proven itself as the most valuable ring-forming method for the construction of six-membered rings at all stages in synthetic execution. Often an intermolecular Diels-Alder reaction is deployed in the first step to generate a cyclohexene- or pyran-containing synthetic intermediate, or in the middle stages an intramolecular Diels-Alder reaction enables formation of a bicyclic decalin system. The title reaction is also frequently used in the ultimate or penultimate step for the generation of a highly complex synthetic target. The versatility of the Diels-Alder reaction in total synthesis is truly remarkable.92 Intermolecular Applications Several groups exploited the power of the intermolecular Diels-Alder reaction early in their syntheses for the formation of substituted cyclohexenes. In his synthesis of platencin, Nicolaou used a Danishefskylike diene in an asymmetric Diels-Alder reaction for the synthesis of a chiral cylohexenone.93 Kanai and Shibasaki developed a catalytic asymmetric Diels-Alder reaction promoted by barium isopropoxide for the first step in their synthesis of Tamiflu.94 Danishefsky constructed the cyclohexene ring in paecilomycine A by employing a highly ewt/o-selective Diels-Alder reaction of siloxydiene 115 and enyne dienophile 116 to yield target 117.95

Name Reactions for Carbocyclic Ring Formations

296 OSiMe3

OSiMe 3 ^.SiMe 3

SiMe?

OHC

''CHO 0 °C, 30 min 58% endo/exo> 20:1

116

115

117

Similarly, pyran rings are a common early-stage synthetic intermediate in a variety of syntheses. In Kutay and Gademann's synthesis of anguinomycin C, they prepare the heterocyclic portion of the target by combination an electron-rich diene with an unsaturated aldehyde in the presence of Jacobsen's chromium (III) catalyst.96 Ghosh used the same asymmetric catalyst to promote the reaction of an aldehyde and an electronrich diene in his synthesis of brevisamide.97 Rawal synthesized a pyranone for use in his synthesis of pederin by combination of a chiral dienophile with Danishefsky's diene.98 In his synthesis of phorboxazole B, Burke treated Brassard diene 119 with chiral aldehyde 118 and a europium catalyst to yield pyranone 120 99 OMe

OMe cat. Eu(fod)3

BnO OBn 118

EtO 119

OSiMe, CH2CI2,0°C

BnO

71%

Intermolecular Diels-Alder reactions are also highly useful for the construction of poly cyclic carbocycles in natural product total syntheses. Rawal combined a cyclohexadienone with a Danishefsky-type diene to yield a c/s-decalin in his total synthesis of platencin.100 Stratakis also generated a cis-decalin upon combination of a quinone dienophile and an acyclic diene during the production of acremine G.101 Nakamura and Hashimoto employed an intermolecular Diels-Alder reaction for the construction of the G ring in pinnatoxin A.102 Danishefsky reacted a vinylindene diene with a quinoneketal dienophile to form the tetracyclic framework of fluostatin C.103

Chapter 4 Six-Membered Carbocycles

297

In Nicolaou's synthesis of the bisanthraquinone antibiotic BE-43472B, he initiated a fascinating late-stage cascade by the reaction of a functionalized acyclic diene with a pentacyclic quinone dienophile.1 In a highly complex example, Nakata performed the penultimate step in the synthesis of sarcophytoate by combining dienophile 121 and diene 122 in a thermal Diels-Alder reaction.105

Intramolecular variants are the most common type of Diels-Alder reactions employed in total syntheses with carbocycles the most popular targets. Among the broad variety of structures in this class, bicyclic decalin structures, both eis and trans, are readily available on intramolecular DielsAlder reactions. Aubé demonstrated the use of a tandem intramolecular Diels-Alder/Schmidt reaction sequence in his synthesis of three stemona alkaloids. The first steps generates cw-decalin intermediate 124, which undergoes a ring expansion in the Schmidt reaction to furnish tricycle 125.10

Name Reactions for Carbocyclic Ring Formations

298

OBn

OBn MeAICI, CH2CI2, 45 °C 43%

OBn

125

Many research groups generate trans-decalins as synthetic intermediates in total syntheses. MacMillan demonstrated the power of his methodology for enantioselective organocatalytic intramolecular Diels-Alder reactions by preparing the trans-decalin framework of solanapyrone in a highly selective cycloaddition.107 Hoye synthesized the /raws-decalin portion of the heteratriquinane UCS1025A via a thermal Diels-Alder reaction.108 Evans deployed an intramolecular Diels-Alder reaction for the synthesis of a bicyclic synthetic intermediate during his synthesis of himgaline.109 Movassaghi prepared the A and B rings of himandrine in an intramolecular Diels-Alder reaction of tetraene 126 to afford frvms-decalin 127. U0 OHC BHT, W,/V-diethylaniline

OHC TBSO

CH3CN, 95 °C OMe

75%

N. H ÖMe

126

Intramolecular Diels-Alder reactions also enable the construction of cyclohexenes in a variety of molecular frameworks. A late-stage cycloaddition generated the tetracyclic skeleton in Wong's synthesis of

Chapter 4 Six-Membered Carbocycles

299

pallavicinolide A.111 Snider and Thomson separately used similar intramolecular Diels-Alder reaction strategies for the synthesis of the key tricyclic framework of deoxysymbioimine and symbioimine, respectively.112'"3 Imagawa and Nishizawa prepared a bicyclic γ-lactone via an intramolecular Diels-Alder reaction in their synthesis of neovibsanin B.114 Corey deployed an enantioselective Diels-Alder macrobicyclization as a key step in the syntheses of palominol, dolabellatrienone, ß-araneosene, and isoedunol.115 Lebel demonstrated the use of a one-pot copper-catalyzed methylenation-Diels-Alder cyclization as the final step in her synthesis of desoxygaliellalactone. Jacobsen generated the pentacyclic framework of yohimbine in a scandium triflate-catalyzed intramolecular Diels-Alder 117

reaction. Kishi synthesized both the macrocyclic and cyclohexene rings in the pteriatoxins via an intramolecular cycloaddition.118 Trauner employed a vinyl quinone as a diene in the Diels-Alder reaction that generated the pentacyclic structure of halenaquinone.119 As demonstrated by Crimmins, the tricyclic core of the eunicellins is readily available from an intramolecular Diels-Alder reaction.120 Three specific examples from Gin, Sorenson, and Baran highlight the power of the standard intramolecular Diels-Alder reaction. Gin developed a 1,3-dipolar cycloaddition and dienamine-Diels-Alder reaction sequence for the synthesis of nominine. The dipolar cycloaddition delivered the precursor to dienone 128 which generates dienamine 129 on exposure to hot pyrrolidine. Cycloaddition of 129 provides desired target 130, which is easily converted into nominine.121 MeOH/pyrrolidine 60 °C 78%

1) Wittig 2) oxidation

129 H

H

130

Sorensen's synthesis of abyssomicin C relied on an intramolecular Diels-Alder reaction catalyzed by lanthanum trillate. Heating 131 in the presence of the Lewis acid catalyst promotes both elimination of the silyl

300

Name Reactions for Carbocyclic Ring Formations

ether and the desired cycloaddition to afford tricycle 132, which is converted into abyssomicin C in three additional steps.122

OCH,

TBSO

In a spectacular final sequence during his synthesis of haouamine A, Baran employed an intramolecular Diels-Alder reaction with alkyne dienophile 133 to yield cycloadduct 134. This material then underwent a retro Diels-Alder reaction (producing carbon dioxide) followed by ester hydrolysis to afford haouamine A. This Diels-Alder/retro-Diels-Alder cascade is remarkable since the benzene ring formed in this sequence is not planar.123 OAc OAc 1 ) o-dichlorobenzene 250 °C, BHT, 10 h 2) K2C03, MeOH, 30 min 21% 133

Chapter 4 Six-Membered Carbocycles

301

haouamine A

Heterocyclic six-membered rings are often prepared during total synthesis investigations using intramolecular Diels-Alder reactions. Nicolaou employed the reaction of an o-quinone diene with a tetrasubstituted alkene to generate the macrocyclic structure of sporolide B,124 while in Nakada's synthesis of FRI 82877, he transformed an acyclic compound into an oxygen-containing tetracycle via an intramolecular Diels-Alder/heteroDiels-Alder cascade.125 Trauner developed a highly productive cascade sequence to complete his synthesis of rubioncolin B. Treatment of 135 with two equivalents of the fluoride reagent TASF and PhI(OAc)2 led directly to TBS-deprotection and oxidation to the /»-quinone which readily tautomerized to the cycloaddition precursor 136. A hetero Diels-Alder reaction followed by demethylation with boron tribromide afforded the target natural product in excellent yield.126 Me02C

\ y

Me02C TBSO. "V

pMe

"OTBS

135

1)2equivTASF, Phl(OAc)2 60% 2) BBr3 95%

».

302

Name Reactions for Carbocyclic Ring Formations

Nitrogen-containing heterocycles are also available via intramolecular hetero Diels-Alder reactions. Williams employed an aza diene to prepare a complex polycyclic synthetic intermediate in his synthesis of versicolamide B.12 Boger reported a tandem intramolecular hetero Diels-Alder/1,3-dipolar cycloaddition sequence for the synthesis of vindorosine. Cycloaddition precursor 137 undergoes an inverse electron demand Diels-Alder reaction to yield 138. This compound decomposes via a retro dipolar cycloaddition to generate nitrogen gas and a 1,3-dipole that completes the cascade by reacting with the indole alkene to afford 139. Seven more steps enable the completion of vindorosine.128

1,3,5-triisopropylbenzene, 230 °C, 60 h C0 2 Me 137

78% 138

7 steps ^N

yr

OAC

I HO *C0 2 Me vindorosine

The final type of intramolecular Diels-Alder reaction that finds wide use in natural product total syntheses is the transannular process. Danishefsky exploited the power of this transformation during an oxidative dearomatization/transannular Diels-Alder cascade in his synthesis of 11 -Odebenzoyltashironin.129 Deslongchamps produced the tricyclic core of cassaine via a transannular intramolecular Diels-Alder reaction.130 The tricyclic c/s-decalin with appended macrocycle framework of superstolide A is also available using this strategy. Roush demonstrated the effectiveness of this approach by heating 140 in toluene to yield cycloadduct 141 that was transformed into superstolide A in four more steps.

303

Chapter 4 Six-Membered Carbocycles

OTBDPS toluene 80 °C, 2 h

MeO~ NBoc

30-35%

140 OTBDPS

MeO'

4 steps NBoc

141

MeOv NHAc

superstolide A

4.7.6

Experimental

BF,' OEto CH2CI2, -30 °C 15

99%

304

Name Reactions for Carbocyclic Ring Formations

c/s-2,3-Dimethyl-l,4,4a,10a-tetrahydrophenanthren-9,10-dione (16):20 BF3«OEt2 (44μί, 0.35 mmol) was added to a solution of 1,2-naphthoquinone (14) (50 mg, 0.32 mmol) in dichloromethane (3 mL) at -78 °C. After 10 min, 2,3-dimethyl-l,3-butadiene (15) (72 μί, 0.63 mmol) was added dropwise. The reaction was allowed to slowly warm to -30 °C and maintained for a further 90 min. The reaction was then cooled to -78 °C and brine (3 mL) was added slowly. The reaction was allowed to warm to rt, and the contents were extracted with hexanes ( 3 x 5 mL). The combined organics were then dried (Na2SC>4), filtered, and excess solvent removed in vacuo to yield 16 as a yellow powder (75 mg, 99%) without need for further purification. MeOH/pyrrolidine 60 °C 78%

130 Alkaloid 130:121 To a solution of 128 (27 mg, 0.0953 mmol, 1 equiv) in MeOH (4.5 mL) was added pyrrolidine (0.5 mL). The reaction was then heated to 60 °C (oil bath) for 4.5 h, at which time TLC showed no remaining starting material. The reaction was allowed to cool to ambient temperature and then concentrated in vacuo. The crude product was purified by flash chromatography (10% methanol in dichloromethane with 1% NH4OH) to give 130 as an orange solid (21 mg, 78%). 4.7.7 1. 2. 3. 4. 5. 6. 7. 8.

References [R] Oppolzer, W. Intermolecular Diels-Alder Reactions. In Comprehensive Organic Synthesis; Trost, B. M, Fleming, I., Eds.; Pergamon: New York, 1991; Vol. 5, pp. 315-399. [R] Roush, W. R. Intramolecular Diels-Alder Reactions. In Comprehensive Organic Synthesis; Trost, B. M., Fleming, I., Eds.; Pergamon: New York, 1991; Vol. 5, pp. 513-550. [R] Boger, D. L. Heterodiene Additions. In Comprehensive Organic Synthesis; Trost, B. M, Fleming, I., Eds.; Pergamon: New York, 1991; Vol. 5, pp. 451-512. [R] Weinreb, S. M. In Comprehensive Organic Synthesis; Trost, B. M, Fleming, I., Eds.; Pergamon: New York, 1991, Vol. 5, pp. 401^149. [R] Fringuelli, F.; Taticchi, A. The Diels-Alder Reaction: Selected Practical Methods Wiley, New York, 2002. [R] Walters, L. R. Kurt Alder and Otto Paul Hermann Diels. In Nobel Laureates in Chemistry 1901-1992; James, L. K. Ed.; ACS CHF, 1993, pp. 328-337. Diels, O.; Alder, K. Justus Liebigs Ann. Chem. 1928, 460, 98-122. [R] Kloetzel, M. C. Org. React. 1948, 4, 1-59.

Chapter 4 Six-Membered Carbocycles

9. 10. 11. 12.

13. 14. 15. 16. 17. 18. 19. 20. 21. 22. 23. 24. 25. 26. 27. 28. 29. 30. 31. 32. 33. 34. 35. 36. 37. 38. 39. 40. 41. 42. 43. 44.

305

[R] For a detailed look at the discovery of the Diels-Alder reaction, see Berson, J. A. Chemical Creativity: Ideas from the Works of Woodward, Huckel, Meerwein, and Others Wiley-VCH, New York, 1999; pp. 9-23. [R] Woodward, R. B.; Hoffmann, R. Angew. Chem., Int. Ed. 1969, 8, 781-853. Alberti, M. N.; Orfanopoulos, M. Org. Lett. 2009,11, 1659-1662. For recent reports exploring regioselectivity in Diels-Alder reactions, see (a) Cui, Y.; Jiang, H.; Li, Z.; Wu, N.; Yang, Z.; Quan, J. Org. Lett. 2009, 11, 4628-4631. (b) Hayden, A. E.; DeChancie, J.; George, A. H.; Dai, M.; Yu, M.; Danishefsky, S. J.; Houk, K. N. / . Org. Chem. 2009, 74, 6770-6776. (c) Hilt, G.; Janikowski, J. Org. Lett. 2009,11, ΊΊ1-ΊΊ6. Inukai, T.; Kojima, T. J. Org. Chem. 1971, 36, 924-928. [R] Sankararaman, S. Pericyclic Reactions—A Textbook: Reactions, Applications, and Theory; Wiley-VCH, New York, 2005, pp. 106-168. Alder, K.; Stein, G. Angew. Chem. 1937, 50, 510. For examples of exo-selective Diels-Alder reactions, see Lam, Y.-H.; Cheong, P. H.-Y.; Mata, J. M. B.; Stanway, S. J.; Gouverneur, V.; Houk, K. N. J. Am. Chem. Soc. 2009, 131, 1947-1957. a) [R] Stajer, G.; Csende, F.; Fulop, F. Curr. Org. Chem. 2003, 7, 1423-1432. b) [R] Sweger, R. W.; Czarnick, A. W. In Comprehensive Organic Synthesis; Trost, B. M., Fleming, I., Eds.; Pergamon: New York, 1991, Vol. 5, pp. 551-592. For the first example (using A1C13), see Yates, P.; Eaton, P. J. Am. Chem. Soc. 1960, 82, 4436-4437. (a) [R] Jorgensen, K. A. Cycloaddition Reactions in Organic Synthesis; Kobayashi, S., Jorgensen, K. A., Eds.; Wiley-VCH: New York, 2002; pp 301-327. (b) [R] Pindur, U.; Lutz, G.; Otto, C. Chem. Rev. 1993, 93, 741-761. Gelman, D. M.; Forsyth, C. M.; Perlmutter, P. Org. Lett. 2009, / / , 4958^1960. [R] Reymond, S.; Cossy, J. Chem. Rev. 2008, 108, 5359-5406. Furstner, A.; Stimson, C. C. Angew. Chem., Int. Ed. 2007, 46, 8845-8849. Ballerini, E.; Minuti, L.; Piermatti, O.; Pizzo, F. J. Org. Chem. 2008, 73, 7909-7915. Sevov, C. S.; Wiest, O. J. Org. Chem. 2009, 74,4311^317. (a) Tiwari, S.; Kumar, A. Angew. Chem., Int. Ed. 2006, 45, 4824-4825. (b) [R] Kumar, A. Chem. Rev. 2001,101, 1-19. Kass, S.; Gregor, T.; Kersting, B. Angew. Chem., Int. Ed. 2006, 45, 101-104. [R] Kelly, W. L. Org. Biomol. Chem. 2008, 6, 4483-4493. Zhang, X.; Bruice, T. C. J. Am. Chem. Soc. 2007, 129, 1001-1007. [R] Shen, J.; Tan, C.-H. Org. Biomol. Chem. 2007, 6, 3229-3236. Liu, W.; You, F.; Mocella, C. J.; Harman, W. D. J. Am. Chem. Soc. 2006, 128, 1426-1427. [R] Kouznetsov, V. Tetrahedron 2009, 65, 2721-2750. [R] Heintzelman, G. R.; Meigh, I. R.; Mahajan, Y. R.; Weinreb, S. M. Org. React. 2005, 65, 141-599. [R] Bansal, R. K.; Kumawat, S. K. Tetrahedron 2008, 64, 10945-10976. [R] Rizzacasa, M. A.; Pollex, A. Org. Biomol. Chem. 2009, 7, 1053-1059. [R] Cacciarini, M.; Menichetti, S.; Nativi, C ; Richichi, B. Curr. Org. Synth. 2007, 4,47-57. [R] Hilt, G. Angew. Chem., Int. Ed. 2009, 48, 6390-6393. Maingot, L.; Leconte, S.; Chataigner, I.; Martel, A.; Dujardin, G. Org. Lett. 2009, 11, 16191622. Yang, B.; Miller, P. A.; Mollmann, U.; Miller, M. J. Org. Lett. 2009, / / , 2828-2831. Li, P.; Yamamoto, H. J. Am. Chem. Soc. 2009, 131, 16628-16629. Sarkar, N.; Banerjee, A.; Nelson, S. G. J. Am. Chem. Soc. 2008, 130, 9222-9223. Catozzi, N.; Edwards, M. G.; Raw, S. A.; Wasnaire, P.; Taylor, R. J. K. J. Org. Chem. 2009, 74, 8343-8354. Shi, B.; Lewis, W.; Campbell, I. B.; Moody, C. J. Org. Lett. 2009, 11, 3686-3688. Blackman, M. L.; Royzen, M.; Fox, J. M. J. Am. Chem. Soc. 2008, 130, 13518-13519. [R] For a review of catalytic asymmetric Diels-Alder reactions, see Hayashi, Y. In Cycloaddition Reactions in Organic Synthesis; Kobayashi, S., Jorgensen, K. A., eds.; WileyVCH, New York, 2002, pp. 5-56.

306 45. 46.

47. 48. 49.

50. 51. 52. 53. 54. 55. 56. 57. 58. 59. 60. 61. 62. 63. 64. 65. 66. 67. 68. 69. 70. 71. 72. 73. 74. 75. 76. 77. 78.

Name Reactions for Carbocyclic Ring Formations [R] For a review of catalytic enantioselective Diels-Alder reactions of carbonyl compounds, see Jorgensen, K. A. Cycloaddition Reactions in Organic Synthesis; Kobayashi, S., Jorgensen, K. A., Eds.; Wiley-VCH: New York, 2002; pp 151-186. [R] For reviews of stereoselective aza Diels-Alder reactions, see (a) Rowland, G. B.; Rowland, E. B.; Zhang, Q.; Antilla, J. C. Curr. Org. Chem. 2006, 10, 981-1005. (b) Kobayashi, S. Cycloaddition Reactions in Organic Synthesis; Kobayashi, S.; Jorgensen, K. A., eds.; Wiley-VCH, New York, 2002, pp. 187-210. [R] For a review of the use of metal-based catalysts in asymmetric Diels-Alder reactions, see Zhu, H. J.; Jiang, J. X.; Ren, J.; Yan, Y. M.; Pittman, C. U., Jr. Curr. Org. Synth. 2005, 2, 547-587. [R] For a review on asymmetric nitroso Diels-Alder reactions, see Yamamoto, Y.; Yamamoto, H. E. J. Org. Chem. 2006, 2031-2043. For recent examples of the use of chiral auxiliaries in diastereoselective hetero Diels-Alder reactions, see (a) Gallier, F.; Hussain, H.; Martel, A.; Kirschning, A.; Dujardin, G. Org. Lett. 2009, 11, 3060-3063. (b) Clark, R. C; Pfeiffer, S. S.; Boger, D. L. J. Am. Chem. Soc. 2006, 128, 2587-2593. Liu, D.; Canales, E.; Corey, E. J. J. Am. Chem. Soc. 2007, 129, 1498-1499. Payette, J. N.; Yamamoto, H. Angew. Chem., Int. Ed. 2009, 48, 8060-8062. Paddon-Row, M. N.; Anderson, C. D.; Houk, K. N. J. Org. Chem. 2009, 74, 861-868. Sakakura, A.; Kondo, R.; Matsumura, Y.; Akakura, M.; Ishihara, K. J. Am. Chem. Soc. 2009, 131, 17762-17764. Esquivias, J.; Arrayas, R. G.; Carretero, J. C. J. Am. Chem. Soc. 2007,129, 1480-1481. Sibi, M. P.; Stanley, L. M.; Nie, X.; Venkatraman, L.; Liu, M.; Jasperse, C. P. J. Am. Chem. Soc. 2007, 129, 395^105. Sibi, M. P.; Kawashima, K.; Stanley, L. M. Org. Lett. 2009, / / , 3894-3897. [R] For a review of proline-catalyzed enantioselective aza Diels-Alder reactions, see Painter, T. O.; Brummond, K. M. Chemtracts 2006,19, 377-384. Singh, R. P.; Bartelson, K.; Wang, Y.; Su, H.; Lu, X.; Deng, L. J. Am. Chem. Soc. 2008, 130, 2422-2423. Gioia, C; Hauville, A.; Bernardi, L.; Fini, F.; Ricci, A. Angew. Chem., Int. Ed. 2008, 47, 9236-9239. Abraham, C. J.; Pauli, D. H.; Scerba, M. T.; Grebinski, J. W.; Lectka, T. J. Am. Chem. Soc. 2006, 128, 13370-13371. Han, B.; He, Z.-Q.; Li, J.-L.; Li, R.; Jiang, K.; Liu, T.-Y.; Chen, Y.-C. Angew. Chem. Int. Ed. 2009, 48, 5474-5477. a) He, M.; Struble, J. R.; Bode, J. W. J. Am. Chem. Soc. 2006, 128, 8418-8420. b) He, M.; Uc, G. J.; Bode, J. W. J. Am. Chem. Soc. 2006, 128, 15088-15089. Kawasaki, M; Yamamoto, H. J. Am. Chem. Soc. 2006,128, 16482-16483. Momiyama, N.; Tabuse, N.; Terada, M. J. Am. Chem. Soc. 2009,131, 12882-12883. Akiyama, T.; Morita, H.; Fuchibe, K. J. Am. Chem. Soc. 2006,128, 13070-13071. Tiwari, S.; Khupse, N.; Kumar, A. J. Org. Chem. 2008, 73, 9075-9083. Halvorsen, G. T.; Roush, W. R. Org. Lett. 2008,10, 5313-5316. Desrat, S.; van de Weghe, P. J. Org. Chem. 2009, 74, 6728-6734. Webster, R.; Lautens, M. Org. Lett. 2009, 11,4688^691. Jung, M. E.; Min, S.-J. J. Am. Chem. Soc. 2005, 127, 10834-10835. Dai, M.; Sarlah, D.; Yu, M.; Danishefsky, S. J.; Jones, G. O.; Houk, K. N. J. Am. Chem. Soc. 2007, 129, 645-647. Kim, W. H.; Lee, J. H.; Danishefsky, S. J. J. Am. Chem. Soc. 2009,131, 12576-12578. Redondo, M. C; Veguillas, M.; Ribagorda, M; Carreno, M. C. Angew. Chem., Int. Ed. 2009, 48, 370-374. Pearson, A. J.; Zhou, Y. J. Org. Chem. 2009, 74, 4242^1245. Hudon, J.; Cernak, T. A.; Ashenhurst, J. A.; Gleason, J. L. Angew. Chem., Int. Ed. 2008, 47, 8885-8888. [R] For a review of asymmetric hetero Diels-Alder reactions of Danishefsky's and Brassard's dienes with aldehydes, see Lin, L.; Liu, X.; Feng, X. Synlett 2007, 2147-2157. Sudo, Y.; Shirasaki, D.; Harada, S.; Nishida, A. J. Am. Chem. Soc. 2008,130, 12588-12589. Chen, I.-H.; Oisaki, K.; Kanai, M; Shibasaki, M. Org. Lett. 2008, 10, 5151-5154.

Chapter 4 Six-Membered Carbocycles 79. 80. 81. 82. 83. 84. 85. 86. 87. 88. 89. 90. 91. 92. 93. 94. 95. 96. 97. 98. 99. 100. 101. 102. 103. 104. 105. 106. 107. 108. 109. 110. 111. 112. 113. 114. 115. 116. 117. 118. 119. 120.

307

Yu, Z.; Liu, X.; Dong, Z.; Xie, M.; Feng, X. Angew. Chem., Int. Ed. 2008, 47, 1308-1311. Newman, C. A.; Antilla, J. C; Chen, P.; Predeus, A. V.; Fielding, L.; Wulff, W. D. J. Am. Chem. Soc. 2007,129, 7216-7217. Mandai, H.; Mandai, K.; Snapper, M. L.; Hoveyda, A. H. J. Am. Chem. Soc. 2008, 130, 17961-17969. For a review of boron- and silicon-substituted dienes, see Welker, M. E. Tetrahedron 2008, (54,11529-11539. Pidaparthi, R. R.; Junker, C. S.; Welker, M. E.; Day, C. S.; Wright, M. W. J. Org. Chem. 2009, 74, 8290-8297. Payne, A. D.; Willis, A. C; Sherburn, M. S. J. Am. Chem. Soc. 2005, 127, 12188-12189. [R] Wessig, P.; Muller, G. Chem. Rev. 2008, 108, 2051-2063. Barluenga, J.; Fernandez-Rodriguez, M. A.; Garcia-Garcia, P.; Aguilar, E. J. Am. Chem. Soc. 2008,130, 2764-2765. [R] Vogel, P. Top. Curr. Chem. 2008,282, 187-214. [R] Although not focused on true tandem/cascade processes, for a review of the synthesis of polycyclics by a combination of enyne metathesis and the Diels-Alder reaction, see Kotha, S.; Meshram, M.; Tiwari, A. Chem. Soc. Rev. 2009, 38, 2065-2092. Berube, A.; Dratu, I.; Wood, J. L. Org. Lett. 2006, 5, 5421-5424. Tietze, L. F.; Bohnke, N.; Dietz, S. Org. Lett. 2009, / / , 2948-2950. Enders, D.; Huttl, M. R. M.; Runsink, J.; Raabe, G.; Wendt, B. Angew. Chem., Int. Ed. 2007, 46,467-469. a) [R] Tadano, K. Eur. J. Org. Chem. 2009, 4381-4394. b) [R] Takao, K.; Munakata, R.; Tadano, K. Chem. Rev. 2005, 105, 4779^1807. c) [R] Nicolaou, K. C; Snyder, S. A.; Montagnon, T.; Vassilikogiannakis, G. Angew. Chem., Int. Ed. 2002, 41, 1668-1698. Nicolaou, K. C; Tria, G. S.; Edmonds, D. J. Angew. Chem., Int. Ed. 2008, 47, 1780-1783. Yamatsugu, K..; Yin, L.; Kamijo, S.; Kimura, Y.; Kanai, M.; Shibasaki, M. Angew. Chem., Int. Ed. 2009, 48, 1070-1076. Min, S.-J.; Danishefsky, S. J. Angew. Chem., Int. Ed. 2007, 46, 2199-2202. Bonazzi, S.; Guttinger, S.; Zemp, I.; Kutay, U.; Gademann, K. Angew. Chem., Int. Ed. 2007, 46, 8707-8710. Ghosh, A. K.; Li, J. Org. Lett. 2009,11,4164-4167. Jewett, J. C; Rawal, V. H. Angew. Chem., Int. Ed. 2007, 46, 6502-6504. Lucas, B. S.; Gopalsamuthiram, V.; Burke, S. D. Angew. Chem., Int. Ed. 2007, 46, 769-772. Hayashida, J.; Rawal, V. H. Angew. Chem., Int. Ed. 2008, 47, 4373^1376. Arkoudis, E.; Lykakis, I. N.; Gryparis, C; Stratakis, M. Org. Lett. 2009, //, 2988-2991. Nakamura, S.; Kikuchi, F.; Hashimoto, S. Angew. Chem., Int. Ed. 2008, 47, 7091-7094. Yu, M.; Danishefsky, S. J. J. Am. Chem. Soc. 2008,130, 2783-2785. Nicolaou, K. C; Lim, Y. H.; Becker, J. Angew. Chem., Int. Ed. 2009, 48, 3444-3448. Ichige, T.; Okano, Y.; Kanoh, N.; Nakata, M. J. Am. Chem. Soc. 2007,129, 9862-9863. Frankowski, K. J.; Golden, J. E.; Zeng, Y.; Lei, Y.; Aubé, J. J. Am. Chem. Soc. 2008, 130, 6018-6024. Wilson, R. M.; Jen, W. S.; MacMillan, D. W. C. J. Am. Chem. Soc. 2005,127, 11616-11617. Hoye, T. R.; Dvornikovs, V. J. Am. Chem. Soc. 2006,126, 2550-2551. Evans, D. A.; Adams, D. J. J. Am. Chem. Soc. 2007, 129, 1048-1049. Movassaghi, M.; Tjandra, M.; Qi, J. J. Am. Chem. Soc. 2009,131, 9648-9650. Dong, J.-Q.; Wong, H. N. C. Angew. Chem., Int. Ed. 2009, 48, 2351-2354. Snider, B. B.; Che, Q. Angew. Chem., Int. Ed. 2006, 45, 932-935. Kim, J.; Thomson, R. J. Angew. Chem., Int. Ed. 2007, 46, 3104-3106. Imagawa, H.; Saijo, H.; Kurisaki, T.; Yamamoto, N.; Kubo, M.; Fukuyama, Y.; Nishizawa, M. Org. Lett. 2009,11, 1253-1255. Snyder, S. A.; Corey, E. J. J. Am. Chem. Soc. 2006,128, 740-742. Lebel, H.; Parmentier, M. Org. Lett. 2007, 9, 3563-3566. Mergott, D. J.; Zuend, S. J.; Jacobsen E. N. Org. Lett. 2008,10, 745-748. Matsuura, F.; Peteres, R.; Anada, M.; Harried, S. S.; Hao, J.; Kishi, Y. J. Am. Chem. Soc. 2006, 128, 7463-7465. Kienzler, M. A.; Suseno, S.; Trauner, D. J. Am. Chem. Soc. 2008, 130, 8604-8605. Crimmins, M. T.; Brown, B. H.; Plake, H. R. J. Am. Chem. Soc. 2006,128, 1371-1378.

308 121. 122. 123. 124. 125. 126. 127. 128. 129. 130. 131.

Name Reactions for Carbocyclic Ring Formations Peese, K. M.; Gin, D. Y. /. Am. Chem. Soc. 2006,128, 8734-8735. Zapf, C. W.; Harrison, B. A.; Drahl, C; Sorensen, E. J. Angew. Chem., Int. Ed. 2005, 44, 6533-6537. Baran, P. S.; Burns, N. Z. J. Am. Chem. Soc. 2006,128, 3908-3909. Nicolaou, K. C; Tang, Y.; Wang, J. Angew. Chem., Int. Ed. 2009, 48, 3449-3453. Tanaka, N.; Suzuki, T.; Matsumura, T.; Hosoya, Y.; Nakada, M. Angew. Chem., Int. Ed. 2005, 44, 2580-2583. Lumb, J.-P.; Choong, K. C; Trauner, D. J. Am. Chem. Soc. 2008,130, 9230-9231. Greshock, T. J.; Grubbs, A. W.; Jiao, P.; Wicklow, D. T.; Gloer, J. B.; Williams, R. M. Angew. Chem., Int. Ed. 2008, 47, 3573-3577. Elliott, G.; Velcicky, J.; Ishikawa, H.; Li, Y.; Boger, D. L. Angew. Chem., Int. Ed. 2006, 45, 620-622. Cook, S. P.; Polara, A.; Danishefsky, S. J. J. Am. Chem. Soc. 2006,128, 16440-16441. Phoenix, S.; Reddy, M. S.; Deslongchamps, P. J. Am. Chem. Soc. 2008, 130, 13989-13995. Tortosa, M.; Yakelis, N. A.; Roush, W. R.J. Org. Chem. 2008, 73, 9657-9667.

Chapter 4 Six-Membered Carbocycles

4.8

309

Dötz Benzannulation

Louis Chupak 4.8.1

Description

RL

.Rs

Cr(CO)5 —

RL

R2 X = OR or NRR' 1

».

R2

"x

2

The Dötz benzannulation reaction (DBR) is the reaction of an α,βunsaturated Fischer carbene with an alkyne to produce a highly substituted phenol. Alternatively, the DBR can be considered a metal templated 3 + 1 + 2 cycloaddition of an allylic carbine (3 carbon unit), carbon monoxide (1 carbon unit), and an alkyne (2 carbon unit). The initial product of the reaction is the arene chromium tricarbonyl complex of the phenol as in 4. These complexes are typically unstable in air such that workup and purification of the product lead to the complete loss of the metal. Chromium is the most often used metal for the benzannulation. Molybdinum, tungsten, and manganese have been used but usually give mixtures of products and require harsh reaction conditions. 4.8.2 Historical Perspective Cr(CO)5

Ph 3 =

Ph O "Cr(CO)3

Karl Heinz Dötz first reported the DBR in 1975 for the reaction of carbene 3 with diphenyl acetylene to give the chromium-coordinated napthol 4.1 Since this disclosure, the reaction has found application for the synthesis of numerous heterocyclic and carbocyclic compounds as described in several

Name Reactions for Carbocyclic Ring Formations

310

reviews.2-6 The DBR has been extensively developed by Dötz and William D. Wulff, and is often reffered to as the Wulff-Dötz reaction. 4.8.3 Mechanism Cr(CO)5 X

Ri

R2

-CO +CO

(OC) 3 CrR L

H<X l i k ^Rs

0

J

O RL

Rs 7

I2

Rs

C)

RL

V^ J! o^Y I5

h

R2

11

(OC)3Cr RL

— RL I Cr(CO)4

R1/Y^X

R2

1

R

Rs

Cr(CO)4

I4

Rs

RL

(OC) 4 Cr^Y Rs Ri-^Y^X R2 I3

(OCkCr-^Y*8 R2 16

The currently accepted mechanism of the DBR is shown above.7-8 The ratedetermining step is thought to be loss of a carbon monoxide ligand to form a coordinatively unsaturated intermediate II. This process can be facilitated thermally or photolytically. An alkyne can then coordinate to form 12. The alkyne inserts into the carbene heteroatom bond to give a new chromium carbene 13. At this point there are at least two possible pathways. In the first pathway, carbon monoxide can insert to provide chromium complexed ketene 14, which undergoes electrocyclization to give the hexadienone 15. Tautomerization completes the reaction to provide the phenol 2. Alternatively, metallacycle 16 can form prior to carbon monoxide insertion. Reductive elimination before carbon monoxide insertion leads to pentadiene 5, a commonly observed by-products of the DBR. Cyclopentanones 6,9'10 cyclobutenones 7, and indenes have also been observed as by-products in the

Chapter 4 Six-Membered Carbocycles

311

DBR. In addition, phenolic esters can arise from attack of the DBR products on to a chromium carbon monoxide ligand or the ketene intermediate 14. 4.8.4

Variations and Improvements

With unsymmetrical acetylenes (RL φ Rs) mixtures of products are usually obtained. The ratio of the products depends on the steric difference between the two substituents. The larger group (RL) is integrated adjacent to the carbon derived from carbon monoxide. Terminal alkynes (Rs = H) are often highly regioselective with little, if any, of the alternative regioisomer observed. The reaction can be used to generate a variety of products: vinyl carbene complexes generate phenols, aryl complexes give naphthols and heteroaryl complexes give benzannulated heterocycles. The DBR is compatible with a wide range of substitutents in the alkyne and the unsaturated carbene side chain allowing for the synthesis of densely substituted phenols and further conversion of these phenols to quinones. In the alkyne partner a wide range of functionality is tolerated. The benzannulation has been reported with alkynes having selenyl,1 nitro, boronate, stannyl, aryl, ester, ketone, amide, acetal, ether, enol ether, sulfide, tosyl, and cyano groups. Modest yields have been observed with electronwithdrawing groups. In the extreme, hexafluorobutyne does not participate at all in the DBR. Unprotected alcohols in the reactants can interrupt the DBR by reacting with the ketene intermediate to produce lactones. Alkynes with two large groups often fail to undergo the electrocyclization step to give the DBR product. Aryl carbene complexes with electron-donating or electronwithdrawing substituents in the ortho-, para-, or meta-positions participate in the DBR. The aryl group can also be naphthyl and heteroaryl such as furan, thiophene, pyrrole, pyrazole, and indole. Simple alkyl substituted vinyl carbene complexes have been extensively examined. The double bond can be in either a cyclic or an acyclic system. As stated above, cyclopentanones, cyclobutenones, and indenes have been observed as by-products in the DBR. Wulff has studied the effect of solvent, chelation, concentration, and alkyne substitution on the product distribution.12 He reported that simple α,β-unsaturated chromium carbene complexes typically show excellent selectivity for the benzannulated product. This selectivity is not sensitive to changes in solvent or substituents on the acetylene. However, the reactions of aryl complexes with acetylenes are very sensitive to the nature of both the solvent and the acetylene. For aryl chromium complexes, the highest selectivities and yields for the benzannulated product arise with solvents of low coordinating ability: hexane and benzene. Solvents with intermediate coordinating ability and small size

312

Name Reactions for Carbocyclic Ring Formations

(acetonitrile) give high selectivity for cyclobutenone formation for reactions with disubstituted acetylenes. Solvents with high coordinating ability (dimethyl formamide) give poor selectivity and produce a considerable amount of indene products. The combination of an o-methoxy group on the aryl substituent, 8, of the carbene complex and acetonitrile as solvent alters the product distribution in favor of the cyclobutenone product. Presumably, the formation of the cyclobutenone is favored by coordination of the ether to the metal center. Amide-like complexes [1, X = -N(CH3)2] react with diethylacetylene in THF to give indene products. Similarly, de Meijere has reported that ß-amines, as in 9, completely alter the reaction course so that no benzannulation is observed.13'14 Cr(CO)5

Cr(CO)5 N " ^

0

Irradition has been used to initiate the DBR. Ultraviolet irradiation allows reactions to occur at temperatures as low as -78 °C. High selectivity for the benzannulated product is seen with simple aryl complexes, but high selectivity for indene products for complexes having a chelating o-methoxy on the aryl ring. It is interesting that the product distribution from the reaction of the o-methoxyphenyl complex with diethylacetylene was found to be dependent on alkyne concentration. One equivalent of alkyne, slow addition of alkyne, or low absolute concentration of alkyne favors the indene product. Reactions performed with excess or high concentrations of alkyne favor benzannulation. The observation, reffered to as the "allochemical effect," was explained as resulting from coordination of reaction intermediates by the alkyne. Thus excess alkyne acts as a ligand to stabilize intermediates along the path to benzannulation. Finally, it was noted that the product distribution was not substantially altered by addition of phosphines, phosphine oxides or sulfides. Seperately Wulff has described the effect on selectivity and yield of substitution on the aryl ring of chromium carbene complexes.15 It was shown that electron-withdrawing groups para- to the chromium carbene increase the chemoselectivity for benzannulation. Substituents in the ortho position are detrimental to phenol formation irrespective of the substituent's electronic nature. Finally, it was shown that large alkoxy groups on the carbene carbon (1, X = OR) give increased yields of the desired phenol product.

Chapter 4 Six-Membered Carbocycles

313

A vinyl group in the ß-position of the carbene, as in 10, can participate in the reaction to form an eight-membered ring.1 However, the course of the reaction is sensitive to the size of the alkyne substituent. With smaller groups, R = «-butyl or benzyl, the octatrienone 11 is observed. When R is the larger i-butyl or trimethylsilyl the cyclohexadienone 12 predominates. "Bu

„BU x ( ° c ) 5 C r ^ O ^

0

V R = n-Bu,54%; Bn, 66% 11

10

ir\°

R = f-Bu, 52%; TMS, 48% 12

A key driver for the development of the DBR has been the increased availability of the requisite chromium carbene. Fischer carbenes undergo a wide variety of useful reactions and a significant effort has been devoted to their synthesis.4'5'17 These carbenes undergo many of the same reactions as esters. The α-hydrogens in 13 are quite acidic, with a pKa of approximately 8, that allows for application of the Aldol condensation to form the vinylsubstituted carbene 14.18'19 Of course, alkynes insert into these carbenes to form new vinyl substituted carbenes 15. However, the absence of a heteroatom on the carbene center makes these poor substrates for the DBR. The classical route to Fischer carbenes is the Fischer route: addition of an organolithium to hexacarbonyl chromium and alkylation with a hard electrophile.20-23 Hoye has also shown that alkyl iodides under phasetransfer conditions can be used to alkylate the lithium alkoxide.24 Thus reaction of vinyl lithium 16 provides the carbene 17 in 53% over two steps. RCHO Et3N, TMS-CI

X = OR or NRR' 13

Name Reactions for Carbocyclic Ring Formations

314

Cr(CO) 5 Li

Cr(CO) 5

Cr(CO)5

Cr(CO) 6

^Λ^

Bu4N+ Br"

16

"OCH 3

17 53%

Alternatively, when the counterion of the initial adduci 18 is exchanged with tetramethyl ammonium, the mixed anhydride can be prepared by reaction with pivaloyl chloride. Further reaction with alcohols or amines then yields chromate esters and amides, respectively. Functional groups can be introduced into the heteroatom-linked chains that are not compatible with alkyl and aryl lithium species. The pimary alkyl iodide 19 was prepared by this method. 5 Cr(CO) 5 O- N + (CH 3 ) 4

LPiv-CI v

OH

19 78%

This acylation strategy was used to prepare polymer-supported chromium carbenes. Microwave irradiation on Wang resin shows the same regioselectivity as solution chemistry but fewer side products. 6 The resinbound phenol 21 is simultaneously released and oxidized to the benzoquinone 22 with ceric ammonium nitrate. Microwave irradiation has been shown to accelerate the DBR and provide high yields of benzannulated products in short reaction times (ca. 5 min).27 CH 3 0

Cr(CO) 5

CH3O

rV? l

\ ^

CH2CI2 MWI 85 °C 20 min.

PL-Wang resin

20 CH3O CAN CH 2 CI 2 / H 2 0 rt, 12 h 22 80%

O-PL-Wang resin

Chapter 4 Six-Membered Carbocycles

315

Chromium carbenes can also be prepared by the so-called Semmelhack-Hegedus route. Chromium hexacarbonyl is first reduced to a nucleophilic pentacarbonyl dichromate dianion 23 with sodium naphthalenide ' or potassium carbide. Reaction of this dianion species with an acid chloride gives a metal alkoxide that can be quenched with an electrophile to provide the desired chromate ester 24. Alternatively, the dianion can be added to an amide carbonyl to give a tetrahedral intermediated which collapses to the chromate amide 25 on treatment with trimethylsilyl chloride. O

Cr(CO)5

J^

1

°*2 24

O

X

-

!-Ri CI LR-fXI 2.

R2X

X

M2[Cr(CO)5] 23

1. FT N R ^ 1. R ^ N ^ F 2.

TMS-CI

-

Cr(CO>'5

R

J^

N

25

Dry state absorbtion conditions, microwave irradtion, and photolysis have all been used to accelerate the DBR. Recently Kerr has described simple conditions that promote the DBR at near ambient conditions.31 His optimized procedure used dichloroethane as the solvent with heating at 30 °C for 18 h with no additives. Dichloroethane and gentle heating were both critical for high yields. It is interesting that ambient laboratory temperature, measured as 14-17 °C, was insufficient and resulted in sluggish reactions. 4.8.5 Synthetic Utility General Utility As stated above, the reaction is highly valuable for both the synthesis of highly substituted phenols and further conversion of these phenols to quinones. Harrity has described optimized conditions for DBR using boronate esters requiring three equivalents of alkyne.32 Anderson applied these conditions toward sytheses of boronate-substituted quinones. Chromium carbene 26 reacts with boronate 27 in 48% yield over two steps to give the quinone 28.33

Name Reactions for Carbocyclic Ring Formations

316

(OC)5Cr^ &ii) CAN

\

// OTBDPS 26

27

28

Complex and highly substituted nitrogen- and oxygen-containing heterocycles such as carbazoles, indoles, cyclophanes, naphthoquinones, and furanocoumarins can be assembled from the DBR. Sen, for example, has used the intramolecular DBR to make oxygen-containing heterocycles in good yield under both the standard DBR conditions and under solvent-free conditions. 4 Alkyne 29 was converted to phenol 30 in 56% yield.

THF 80 °C 30 56%

29

Pulley has reported using the DBR as a strategy to prepare the amino acids isodityrosines35 and aryl glycines.36 The styrene-derived carbene 31 reacted with the alkyne 32 to provide the phenol 33 in 87% yield. An interesting observation was that the yields were significantly higher with ultrasonication (59-87%) than with thermal (51-69%) conditions. The targeted amino acid 34 was produced using standard transformations.

Cr(CO)5 \ ^

))) Roc Boc

31

32

V-NBocOH 33 87%

^ ^

Chapter 4 Six-Membered Carbocycles

317

HO CbzHN 34

The control of stereochemistry with chromium carbine complexes has been reviewed.37 The DBR can create a new stereocenter in three ways. First, the arene tricarbonyl chromium complex contains a plane of chriality, thus the complexes 35 and ent-35 are enantiomers when RL Φ Ri and RS Φ R2. Second, when phenyl substituents are included in the reactants the resulting biaryls can posess axial chirality if there is hindered rotation about the new aryl—aryl bond as in 36.38 Finally, all DBRs with differentially ßdisubstitued alkenes give rise to cyclohexadienones 37 with a new stereocenter adjacent to the carbonyl. When Ri and R2 are not hydrogen, tautomerization cannot occur and the final product possesses a chiral center. (OC)3Cr^

(OC) 3 CrR L

RL

R2

eni-35

37

enantiomeric chromium arenes

Dötz has reviewed the use of chiral centers in either the alkyne or chromium carbene to control the facial selectivity of the chromium arene complex.6 Examples of these diastereoselective benzannulations exist with the controlling stereocenter in the alkyne, the chromate ester (or amide), or the unsaturated carbene. Anderson has studied the transfer of chirality from a substituent ortho to the alkyne, as in 39, to axial chirality in the biaryl 40.40 He observed that there is a steric balance where a large ortho substituent is required for efficient chirality transfer, but too large a substituent hinders the DBR.

Name Reactions for Carbocyclic Ring Formations

318

Cr(CO)5

Ph O-S.

OH i)75°C2h |/ - ^ ^ ^ ^ ^ on silica ^. ii) air /O

^ V

38

39

O'Hh

40 44% 5:1 dr

Wulff has studied the use of chiral auxiliaries in the chromate ester (1, X = a chiral auxiliary) to control the absolute stereochemistry of the aryl chromium product 35.41 In the same disclosure he describes an attempt to control the chiral center adjacent to the ketone formed on electrocyclization. In his example, a pair of chromium carbene atropisomers 41 (only one shown) were prepared. These diastereomers were readily seperable on silica gel. It was shown that each diastereomeric atropisomer reacted stereospecifically with alkynes to produce a different diastereomer 42. Thus the chiral auxiliary allowed the separation of the atropisomers, but did not directly control the absolute stereochemistry adjacent to the ketone. Instead, the stereochemistry was determined by confining the chromium to one face of the indole in 41 by preventing rotation about the the carbene indole bond.

(OC^Cr^^N Hindered rotation results in seperable atropisomers.

42 40% 95% de

There remain opportunities for further developments in asymmetric induction with the DBR. The generation of axial chirality and control of the stereochemistry a to the ketone are under explored. Finally, to the best of our knowledge, there are no reports of using chiral-coordinating groups to influence the stereochemistry.37 Applications in the total synthesis of natural products Quinones are obvious synthetic targets for the DBR.A2-4A Quinones are numerous, occuring in many biologically active compounds and natural products. Fernandes prepared the quinone (-)-juglomycin A 44 in eight steps

Chapter 4 Six-Membered Carbocycles

319

.45 in 19% overall yield and > 99% ee.^ The quinone core 43 was rapidly assembled using the DBR and the absolute stereochemistry set with an asymmetric dihydroxylation. A similar strategy was used to prepare the eluetherins.46

TBDMSO OTBDMS

OH O 44 (-)-juglomycin A

The intermolecular DBR has been used to prepare a variety of interesting synthetic targets. Quayle has reported a formal total synthesis of aflatoxin B2 using the DBR. 7 Reaction of the acetal-containing chromium carbene 45 with an electron rich alkyne occured in 31% yield to give 46, an advance intermediate for the preparation of aflatoxin. TBDMS

HCL J \ ^<X

Cr(CO)5 \

O z=

TBDMS

THF 80 °C 2h

320

Name Reactions for Carbocyclic Ring Formations

47 (-)-kendomycin

The DBR has been used to prepare the densely functionalized aryl ring found in the ansa macrocyles such as kendomycin 47 48 and arnebinol 48. Two approaches to this group of targets have been desribed. In the first, the aryl ring is formed in the DBR followed with macrocylization. In the second strategy, the DBR is used to simultaneously control the arene substitution pattern and close the macrocyclic ring. Saikawa and Nakata have applied the DBR to the synthesis of the meta-cyclophane arnebiol 48 using the second strategy. In their approach, the macrocyclic ring is formed via an intramolecular DBR of chromium carbene 49. In the absence of a tether, sterics would be expected to dominate the regiochemical outcome. Thus the larger alkyne substituent would be incorporated ortho to the hydroxyl as in 51. They show that a short tether provides the complementary regiochemistry observed in 50. When chain length is increased sterics dominate the regiochemical course of the reaction. When « is 2 through to 4 only the ort/20-cyclophane 50 and the dimer, resulting from intermolecular DBR, are observed. When n is increased to 5 through 13, only the meta- cyclophane is isolated. This strategy resulted in DBR to produce arnebinol 48 in 49% yield when the tether contained eight carbons (n = 6), including two .E-alkenes. Wulff applied a similar strategy to form macrocyclic cyclohexadienes as intermediates toward synthesis of phomactin natural products.50 In one example, a 13-membered ring macrocycle 53 formed in 64% yield from the acyclic precursor 52. As with the cyclophanes, attempts to produce medium-size rings gave only the dimer from intermolecular reaction.

A: Cr(CO) 5

(CH2)n 49

O

OH 50

(CH2)n

0-Λ.

OH 51

Chapter 4 Six-Membered Carbocycles

321

100 °C CH 3 CN

In summary, the DBR is a powerfull method for the construction of highly substituted phenols, quinones, and heterocycles. Significant effort has gone into exploring the scope of the reaction since its initial discovery. This exploration has enabled the confident prediction of regiochemistry and the application to total synthesis. Further efforts to predict and control stereochemistry are needed to increase the utility of this valuable reaction. 4.8.6 Experimental 4.8.6.1 Preparation of lipoxygenase inhibitor 2-butyl-451,52 methoxynaphthalen-1-yl acetate 55 OAc

Cr(CO) 5

il^V^OCHg Il

J

54

-

"C4H1 4π9

Ac20 TEA 55

ocm

An oven-dried, 2-L, three-necked, round-bottomed flask, equipped with a nitrogen inlet, magnetic stirring bar, thermometer, and reflux condenser, under an inert nitrogen atmosphere, is charged with 1.22 g (10 mmol) 4dimethylaminopyridine, 500 mL tetrahydrofuran, 11.0 mL (95.7 mmol) of 1hexyne, 13.2 mL (140 mmol) acetic anhydride, 9.8 mL (70mmol) of triethylamine), 20.0 g (64.0 mmol) of pentacarbonyl[phenyl(methoxy)chromium] carbene 54, and a final 100-mL rinse of tetrahydrofuran. The solution is heated to reflux with an oil bath and heating is maintained until TLC indicates that the chromium complex is totally consumed (45-60 min). The solution is then cooled to ambient temperature, 30 g silica gel is added, and volatile organic material is removed under reduced pressure (rotary evaporator). The green solids are transferred to a filter funnel and washed with hexane until TLC indicates that all products have been removed (5 χ 100 mL). The hexane filtrate is then concentrated under reduced pressure to

322

Name Reactions for Carbocyclic Ring Formations

give crude product contaminated with chromium hexacarbonyl. To the mixture is added 20 mL of isopropyl alcohol, and the insoluble chromium hexacarbonyl is removed by filtration. The filtrate is concentrated under reduced pressure to give 14.0 g crude product, which is purified by silica gel chromatography. Appropriate fractions are combined, and the solvent is removed under reduced pressure to give 1-acetoxy-2-butyl-4methoxynaphthalene (11.8 g, > 95% pure based on HPLC, 68% yield based on the carbene complex as a light yellow oil that crystallizes on standing. If desired, the product can be crystallized from isopropyl alcohol (2.5 mL/g) to give white crystals, m.p. 49-50 °C (> 99% pure based on HPLC). 4.8.7 References 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18. 19. 20. 21. 22. 23. 24. 25. 26. 27. 28. 29. 30. 31. 32.

Dötz, K. H. Angew. Chem. 1975, 87, 672-673. [R] Dötz, K. H.; Tomuschat, P. Chem. Soc. Rev. 1999,28, 187-198. [R] Dötz, K. H.; Stendel, J. Chem. Rev. 2009,109, 3227-3274. [R] Haase, W.-C; Nieger, M.; Dötz, K. H. J. Organomet. Chem. 2003, 684, 153-169. [R] De Meijere, A.; Schirmer, H.; Duetsch, M. Angew. Chem., Int. Ed. 2000, 39, 3964-4002. [R] Minarti, A.; Dötz, K. H. Top. Organomet. Chem. 2004, 13, 123-156. Barluenga, J.; Aznar, F.; Gutierrez, I.; Martin, A.; Garcia-Granda, S.; Amparo LlorcaBaragafio, M. J. Am. Chem. Soc. 2000,122, 1314-1324. Torrent, M.; Duran, M.; Sola, M. J. Am. Chem. Soc. 1999,121, 1309-1316. Eastham, S. A.; Herbert, J.; Ingham, S. P.; Quayle, P.; Wolfendale, M. Tetrahedron Lett. 2006, 47, 6627-6633. Eastham, S. A.; Ingham, S. P.; Hallett, M. R.; Herbert, J.; Quayle, P.; Raftery, J. Tetrahedron Lett. 2006, 47, 2299-2304. Caldwell, J. J.; Colman, R.; Kerr, W. J.; Magennis, E. J. Synlett 2001, 1428-1430. Chan, K. S.; Peterson, G. A.; Brandvold, T. A.; Faron, K. L.; Challener, C. A.; Hyldahl, C; Wulff, W. D. J. Organomet. Chem. 1987, 334, 9-56. Flynn, B. L.; Schirmer, H.; Duetsch, M.; De Meijere, A. J. Org. Chem. 2001, 66, 1747-1754. Wu, Y.-T.; Vidovic, D.; Magull, J.; de Meijere, A. Eur. J. Org. Chem. 2005, 1625-1636. Liptak, V. P.; Wulff, W. D. Tetrahedron 2000, 56, 10229-10247. Barluenga, J.; Fananäs-Mastral, M.; Angel Palomero, M.; Aznar, F.; Valdds, C. Chem.—Eur. J. 2007,13, 7682-7700. Barluenga, J.; Martinez, S. ARK1VOC 2006, 129-147. Wang, H.; Hsung, R. P.; Wulff, W. D. Tetrahedron Lett. 1998, 39, 1849-1852. Lattuada, L.; Licandro, E.; Maiorana, S.; Papagni, A. J. Chem. Soc, Chem. Commun. 1991, 437^38. Aumann, R.; Fischer, E. O. Angew. Chem., Int. Ed. Engl. 1967, 6, 879-880. Casey, C. P.; Cyr, C. R.; Boggs, R. A. Syn. Inorg. Metal-Org. Chem. 1973, 3,249-254. Xu, Y. C; Wulff, W. D. J. Org. Chem. 1987, 52, 3263-3275. Hegedus, L. S.; McGuire, M. A.; Schultze, L. M. Org. Synth. 1993, 8, 216. Hoye, T. R.; Chen, K.; Vyvyan, J. R. Organometallics 1993,12, 2806-9. Barluenga, J.; Perez-Sanchez, I.; Suero, M. G.; Rubio, E.; Florez, J. Chem. Eur. J. 2006,12, 7225-7235. Shanmugasundaram, M.; Garcia-Martinez, I.; Li, Q.; Estrada, A.; Martinez, N. E.; Martinez, L. E. Tetrahedron Lett. 2005, 46, 7545-7548. Hutchinson, E. J.; Kerr, W. J.; Magennis, E. J. Chem. Commun. 2002, 2262-2263. Semmelhack, M. F.; Lee, G. R. Organometallics 1987, 6, 1839-1844. Imwinkelried, R.; Hegedus, L. S. Organometallics 1988, 7, 702-706. Schwindt, M. A.; Lejon, T.; Hegedus, L. S. Organometallics 1990, 9, 2814-2819. Irvine, S.; Kerr, W. J.; McPherson, A. R.; Pearson, C. M. Tetrahedron 2008, 64, 926-935. Davies, M. W.; Johnson, C. N.; Harrity, J. P. A. J. Org. Chem. 2001, 66, 3525-3532.

Chapter 4 Six-Membered Carbocycles 33. 34. 35. 36. 37. 38. 39. 40. 41. 42. 43. 44. 45. 46. 47. 48. 49. 50. 51. 52.

323

Anderson, J. C; Denton, R. M.; Hickin, H. G.; Wilson, C. Tetrahedron 2004, 60, 2327-2335. Sen, S.; Kulkarni, P.; Borate, K.; Pai, N. R. Tetrahedron Lett. 2009, 50,4128^131. Gupta, A.; Sen, S.; Harmata, M.; Pulley, S. R. J. Org. Chem. 2005, 70, 7422-7425. Pulley, S. R.; Czakó, B.; Brown, G. D. Tetrahedron Lett. 2005, 46, 9039-9042. [R] Santamaria, J. Curr. Org. Chem. 2009,13, 31^16. Vorogushin, A. V.; Wulff, W. D.; Hansen, H.-J. Tetrahedron 2007, 64, 949-968. Barluenga, J.; Panday, N.; Santamaria, J.; de Prado, A.; Tomas, M. ARK1VOC 2003, 576583. Anderson, J. C; Cran, J. W.; King, N. P. Tetrahedron Lett. 2003, 44, 7771-7774. Hsung, R. P.; Wulff, W. D.; Chamberlin, S.; Liu, Y.; Liu, R.-Y.; Wang, H.; Quinn, J. F.; Wang, S. L. B.; Rheingold, A. L. Synthesis 2001, 200-220. Caldwell, J. J.; Colman, R.; Kerr, W. J.; Magennis, E. J. Synlett 2001, 1428-1430. Roush, W. R.; Neitz, R. J. J. Org. Chem. 2004, 69,4906-4912. Pulley, S. R.; Czakó, B. Tetrahedron Lett. 2004, 45, 5511-5514. Fernandes, R. A.; Chavan, V. P. Tetrahedron Lett. 2008, 49, 3899-3901. Fernandes, R. A.; Chavan, V. P.; Ingle, A. B. Tetrahedron Lett. 2008, 49, 6341-6343. Eastham, S. A.; Ingham, S. P.; Hallett, M. R.; Herbert, J.; Quayle, P.; Raftery, J. Tetrahedron Lett. 2006, 47, 2299-2304. White, J. D.; Smits, H. Org. Lett. 2005, 7, 235-238. Watanabe, M.; Tanaka, K.; Saikawa, Y.; Nakata, M. Tetrahedron Lett. 2007, 48, 203-206. Huang, J.; Wang, H.; Wu, C; Wulff, W. D. Org. Lett. 2007, 9, 2799-2802. Yamashita, A.; Timko, J. M.; Watt, W. Tetrahedron Lett. 1988, 29, 2513-2516. Timko, J. M; Yamashita, A. Org. Synth. 1993, 71, 72-76.

324

4.9

Name Reactions for Carbocyclic Ring Formations

Elbs Reaction

Timothy T. Curran 4.9.1

Description

The Elbs reaction is the cyclic condensation of an OAt/zo-methyl- or methylene-substituted diaryl ketone 1 to form the corresponding anthracene adduct 2. The reaction is typically promoted thermally, occurs at relatively high temperatures (> 300 °C), and provides an equivalent of water.

R 1

4.9.2

R 2

Historical Perspective

In the late 1800s Elbs and co-workers explored the generality and synthetic utility of what is known as the Elbs reaction. While Elbs was not the first to report this pyrolytic, cyclic condensation reaction,1 the reaction bears his name due to his study of the scope of the reaction.

During his study of preparing simple anthracene homologues like 4, Elbs determined many limitations of the reaction, including low yield and instances in which the Elbs reaction did not give rise to the desired product. Elbs largely discounted the reaction due to these findings along with the fact that other methods were being developed that could prove superior to the Elbs reaction. However, the reaction continues to be used despite its shortcomings due to the ease at which one may assemble the substrate for cyclization and conduct the reaction leading to fairly complicated polyaromatic compounds. Isolation of products has oftentimes been difficult

Chapter 4 Six-Membered Carbocycles

325

and sometimes requires multiple purification tools in the synthetic chemists' toolbox (chromatography, distillation, crystallization of parents or derivatives, sublimation, etc.) to provide pure materials. 4.9.3 Mechanism The mechanism of the Elbs reaction has not been fully vetted.1 Cook suggested tautomerization of the ketone 5 into dienol 6, followed by cyclization forming anthrenol 7. Subsequent hydride transfer or an additional tautomerie shift of hydrogen to provide dihydroanthrol 8, followed by water elimination, provides anthracene 9. Fieser suggested an alternative cyclization step by 1,4-addition of the methyl substituent (without explicit description the methyl species) into the aryl system with the bulk of the intermediates remaining the same as those suggested by Cook. While both of these mechanisms are reasonable, neither author provided sufficient evidence to support their proposal.1

5

6

1,3-H shift or

anthrenol 7

HoO

» tautomerization dihydroanthrol 8

Hurd and Azorlosa2 performed deuterium labelling experiments of two different substrates 10 and 15. They subjected these two deuterated omethylated-diaryl ketones to Elbs conditions and monitored where the deuterium went. Subsequent oxidation of the product mixture was used to determine the relative amount of %d vs. 9d formation. The fact that more Sd isomer was formed than 9d isomer is consistent with deuterium isotope effects. The authors found that < 1% of deuterium remained in the water derived from the reaction. The authors suggested that the low percentage of deuterium in the products was due to subsequent by-product formation. These experiments support a transfer of the aromatic H(D) (hydride transfer

326

Name Reactions for Carbocyclic Ring Formations

or tautomerie shift mentioned above—conversion of 7 into 8) even though such a shift is a forbidden transformation when considering orbital symmetry arguments. It is thought that the extreme conditions used to promote the Elbs reaction can overcome this; perhaps this is a radical or nonconcerted process. In addition, a crossover experiment showed that the d-atom of an o-deuteroketone is not active enough to exchange at 340 °C. Me O

Me R = H, 10 325-334 °C, 11%

R=H,11

R = Me, 15

R = H, 12 R = Me, 17 Compounds

Amt. of D rei. to 10 or 15

11 and 12

0.79

16 and 17

0.67

13 and 14

0.61

18 and 19

0.51

Dauben investigated the mechanism by employing a 14C-labeled carbonyl in an Elbs reaction.3 In this study, he and his co-workers showed that volatile by-products, which were trapped and analyzed accounted for 35% of the radioactivity taken into the reaction. The authors also suggested that optimum yield occurred after about 3 h of reaction time at elevated temperature for the conversion of diarylketone 20 into dibenzanthracene 21.

435 °C 18%

More recently, due to the identification of anthrone and anthroquinone by-products, Badger and Pettit4 along with Buu-Hoi and co-

Chapter 4 Six-Membered Carbocycles

327

workers5 have suggested mechanisms to account for the formation of these by-products. Badger and Pettit suggested a radical mechanism with the first step of the reaction being generation of the benzyl (benzoyl allylogue) radical generating 22. Cyclization of 22 then provides 23, which, depending on the preferred electronics of the molecule, may undergo loss of H· to provide anthrone 24 or abstract an H· to generate anthrenol 7. Oxidation of anthrone to anthraquinone structures are known.4 Formation of anthrenol 7 intercepts the previously suggested mechanism for the Elbs reaction and requires H· migration forming dihydroanthrol 8, which required loss of water to provide anthracene 9.

An additional comment from these authors supported the notion that during the pyrolysis, hydrogen species capable of reducing intermediates were present. Evidence for this was provided in the isolation of 26 from 25.

Buu-Hoi and co-workers suggested a more direct formation of the anthrone by dehydrogenation-cyclization of the starting ketone or dehydrogenation of the dihyroanthrol 8 via a hydrogen donor-acceptor mechanism with the involvement of O2.

328

4.9.4

Name Reactions for Carbocyclic Ring Formations

Variation and Improvements

Use of Additives While there has been no general method for the catalysis of the Elbs reaction, various additives have been used. From the mechanistic discussion above, running the reaction in the presence of atmospheric O2 could have a diminishing impact on the yield of the reaction due to the formation of byproducts like anthrone and anthraquinones. While some have claimed additives to improve the yield, more systematic studies by others have been less conclusive. For instance, the addition of Zn was reported to provide superior yield yet after looking into the details of some side-by-side reactions, Zn offered marginal improvements.1 One positive observation using Zn was reported by Fieser and Hershberg in which the cychzation of 27 with excess Zn occurred more rapidly forming 28 than cychzation without Zn. In additional, an interesting electronic effect was noted when comparing the cychzation of the ß-methyl napthyl ketone with the tolyl naphthyl ketone system. The improved yield for the cychzation of 27 over 29 was presumably due to the preferred addition of the methyl group into the more reactive naphthoyl ring system over the benzoyl ring system.

Other additives surveyed and reported to have little effect on improving the Elbs reaction were H2SO4, KHSO4, P2O5, ZnCk, and piperidine/Ac20. Some surprises in promoting the reaction have come from studies looking at general aryl cyclizations. For example, Vingiello and coworkers6 reported the Elbs product 31 while studying conditions to promote the formation of the cyclodehydration product 32. Quite to their surprise, the Elbs product was formed in significant amounts and at relatively low

Chapter 4 Six-Membered Carbocycles

329

temperature when promoted with AcOH/48% HBr and nearly exclusively using AI2O3.

30

31 Conditions Yield 3 1 36% AcOH,48%HBr, sealed tube, 180 °C Al 2 0 3 , 240-270 °C

49 o /o

32 Yield 32 4 5 %

4 o /o

In a subsequent report,7 Vingiello described a more thorough investigation into these conditions in which Elbs conditions (415^30 °C, Zn) were applied to promote the cyclization and gave a 32% yield of 31; no 32 was observed nor believed to be formed. Vingiello ascribed the general acid or base catalysis in this system to be due to the formation of the Cook type intermediate 6 for the Elbs reaction. In addition a methyl or trifluoromethyl /w-substituent on ring "a" gave only cyclodehydration product or no reaction, respectively. The absence of the Elbs product was ascribed to steric (conformation in which the Me group creates steric issues with the Cook intermediate 6) and electronic effects (the ring for the cyclodehydration reaction becoming too electron deficient). Anomalies due to Elimination or Rearrangement Several anomalies have been observed during studies of the Elbs reaction. There has been the elimination or loss of several groups in a variety of aromatic positions under the high temperature required for the reaction to occur. Loss of both methoxy and chlora groups para to the carbonyl of the aromatic ring that is attacked by the methylene group was reported by Fieser.8 Thus cyclization of 33 gave no detectable amount of the methoxy compound 34 and only a 1% isolated yield of 36 was obtained from 35.

330

Name Reactions for Carbocyclic Ring Formations

33, R = OMe 35, R = CI

34, R = OMe, 0% 36, R = CI, 1%

A report by Bergmann and Blum9 proposed elimination from the dihydroanthranol derivative 37 after tautomerization to 38 and elimination via push of the enol providing 24 or alternatively via HF elimination to aromatize the system (not shown). In the event, fluoroketone 39 gave a 10% yield of dibenzanthracene 40; no fluorodibenzanthracene was detected.10

H H 37

H H 38

H

24

More recently, Newman reported the attempt to synthesize a variety of methylcholanthrene derivatives. The work reported confirmed the above work and determined additional sites in which elimination of certain groups occurred. The authors were able to synthesize the corresponding 8-fluoroand lO-fluoro-3-methylcholanthrenes 42 and 44 via the Elbs reaction in 21% and 47% yields from the corresponding ketones 41 and 43, respectively. However, the Elbs reaction starting with appropriately substituted substrates failed to provide the corresponding 10-methoxy, 11 -methoxy, 11 -fluoro-and 12-fluoro-3-methylcholanthrene derivatives. The 8-methoxy- and 9methoxycholanthrene derivatives have previously been reported.

Chapter 4 Six-Membered Carbocycles

41,R=F, R'= R" = H 43, R' = F, R = R" = H

331

42, R = F, R'= R" = H;21% 44, R' = F, R = R" = H; 47%

Another anomalous reaction was shown by Newman.12 in which an optically enriched substrate 45 was taken into the Elbs reaction and yielded completely racemic product 46.

Due to the findings of Dauben cited in the mechanistic section, it should not be surprising to find that rearrangement of the carbonyl does sometimes occur prior to cyclization. An example of such a rearrangement was reported by the Cook group1 in which two different isomerie naphthyl ketones 47 and 48 gave the same mixture of Elbs products 49 and 50.

50, minor

There also have been rearrangements reported after cyclization. This was reported by several authors, most notably by Badger and Christie 1314 and confirmed in a similar series of more substituted benzothiaphenyl-tolyl

332

Name Reactions for Carbocyclic Ring Formations

substrates by Buu-Hoi and co-workers.15 The rearrangement proved specific for the benzothiaphenyl-tolylketones like 51 was shown to be the exception rather than the rule. The authors suggested that the initial cyclization occurred followed by a subsequent radical formation by lysis of the S-C bond to form 54 which then recombined to form 55. Elimination of H2O then provided the product 52 which was isolated in 37% yield. A byproduct, quinone 57, arising from oxidation of the normal Elbs product, was also reported in 4%.

Further proof of the transformation taking place as suggested, or at least demonstration that an intermediate was being intercepted, was given by preparing the expected Elbs product 56 via another route and subjecting that material to pyrolysis (390 °C, 3 h). Over 60% of 56 was recovered, unchanged.

Badger and Christie13 subsequently studied the Elbs reaction of several benzothiaphenylnaphthyl ketones, which provided the normal Elbs product. Ketone 58 was pyrolyzed neat at 450 °C and provided a 54% yield of the thianaphthofluorene 59.

Chapter 4 Six-Membered Carbocycles

333

450 °C, »reflux, neat 54%

Heterocycles Employed In addition to the benzothiaphenyl system, indolyl ketones,16 pyridyl ketones, quinolyl ketones,4 and dibenzofuryl ketones17 have all provided Elbs products when subjected to pyrolysis conditions. Typically, yields have been in the 5-30% range. Photochemical Promoted Me O)

Me * 0

(*CH 2 OH

CH2 OH

There have been two reports of using light to promote this reaction.1 ' These studies support the Cook intermediate 6 and also the oxidative byproducts previously mentioned. The reaction was proposed to initiate via a type II Norrish reaction forming 62, which rearranges into a mixture of two dienols. Dienol 64 proved analogous to the Cook intermediate and the believed productive compound to undergo Elbs cyclization to 65. Further

334

Name Reactions for Carbocyclic Ring Formations

oxidative by-products were observed under the reaction conditions and anthrone 66 and anthraquinone 67 was identified. 4.9.5 Synthetic Utility The Elbs reaction provides rapid access to polyaromatic systems, particularly due to the ease of preparing many substrates for the reaction. When the Elbs reaction proceeds smoothly, it may provide the best known means to synthesize a certain substrate. For example, 3-methylcholanthrene and derivatives have been shown to be potent carcinogenic agents. The reaction has been used to prepare several methylcholanthrene analogues and other polyaromatic species, the products were isolated and tested in carcinogenic studies to probe characteristics of polyaromatics as potential carcinogenic agents. ' ' ' Despite some of its limitations, the Elbs reaction still offers an easy entry into these complicated polyaromatics.11 4.9.6 Experimental Preparation of lO-fluoro-3-methylcholanthrene (44)u

Ketone 43 (2 g) was heated at 405—410 °C for 30 min by means of a sodium nitrate-potassium nitrite salt bath. The product was chromatographed on neutral alumina using benzene-petroleum ether (1:3) to yield 0.9 g (47%) 44 as pale yellow prisms, m.p. 208-209 °C. 4.9.7 References 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12.

[R] Fieser, L. F. Org. Reac. 1,1942, 129-154. Hurd, C. D.; Azorlosa, J. J. Am. Chem. Soc. 1951, 73, 37^11. Heidelberger, C; Brewer, P.; Dauben, W. G. J. Am. Chem. Soc. 1947, 69, 1389-1391. Badger, G. M.; Pettit, R. J. Chem. Soc. 1953, 2774-2778. Buu-Hoi, N. P.; Marie, C; Jacquignon, P. Bull. Chem. Soc. Fr. 1970, 3, 1012-1015. Vingiello, F. A.; Borkovec, A.; Zajac, W. J. Am. Chem. Soc. 1958, 80, 1714-1716. Vingiello, F. A.; Thornton, J. R. J. Org. Chem. 1966, 31, 659-663. Fieser, L.; Desreux, V. J. Am. Chem. Soc. 1938, 60, 2255-2262. Bergmann, E. D.; Blum J. J. Org. Chem. 1960, 25, 474-475. Bergmann, E. D.; Blum, J. J. Org. Chem. 1961, 26, 3214-3216. Newman, M. S.; Khanna, V. K. J. Org. Chem. 1980, 45,4507^1508. Newman, M. S.; Linsk, J. J. Org. Chem. 1949,14, 480-483.

Chapter 4 Six-Membered Carbocycles 13. 14. 15. 16. 17. 18. 19. 20.

Badger, O. M.; Christie, B. J. J. Chem. Soc. 1958, 913-915. Badger, G. M.; Christie, B. J. J. Chem. Soc. 1956, 3435-3437. Marie, C; Buu-Hoi, N. P.; Jacquignon, P. J. Chem. Soc. (C) 1971,431-434. Buu-Hoi, N. P.; Hoan, N.; Khoi, N. H. J. Org. Chem. 1950,15, 131-134. Buu-Hoi, N. P.; Lavit, D. J. Chem. Soc. 1959, 38-41. Porter, G.; Tchir, M. F. J. Chem. Soc, Chem. Commun. 1970, 1372-1373. Heindel, N. D.; Molnar, J. J. Chem. Soc, Chem. Commun. 1970, 1373-1374. Cook, J. W.; de Worms, C. G. M. J. Chem. Soc. 1937, 1825-1828.

335

336

Name Reactions for Carbocyclic Ring Formations

4.10 Fujimoto-Belleau Reaction Nadia M. Ahmad 4.10.1 Description The Fujimoto-Belleau reaction involves the formation of cyclic cc-substituted a,/?-unsaturated ketones from enols.

4.10.2

Historical Perspective

The Fujimoto-Belleau reaction was reported independently by both George I. Fujimoto and Bernard Belleau in 1951. Fujimoto was attempting to isotopically label steroids in the A ring using a previously reported synthetic method. ' However, he found that a modification of said synthesis resulted in a rearrangement which gave a labeled carbon in the 4'-position. His modification consisted of a Grignard reaction followed by treatment with alkali affording the desired product in good yields of 52-60% without isolation of the intermediate. The reaction was applied to testosterone, whereby a methyl Grignard reagent was added to the enol lactone 3. Cyclisation in the presence of alkali gave testosterone acetate 5 in overall yields of 25-50%. 2 OCOCH 3

OCOCH3

Chapter 4 Six-Membered Carbocycles

337

OCOCH3 "OH 1,2-dimethylphenanthrene

Belleau also reported this reaction in his paper titled "The Reaction of Methylmagnesium Iodide with ß-(l-Hydroxy-3,4-dihydro-2-naphthyl)butyric Acid Lactone."3 Published in the same volume, Belleau described the synthesis of 1,3-dimethylphenanthrene. In this synthesis, enol lactone 6 was converted to ketone 7 by reaction with methylmagnesium iodide and subsequent treatment with hydrochloric acid in 15% yield. The side product of this reaction had an empirical formula of CieHig, which when dehydrogenated gave 1,3-dimethylphenanthrene, the actual synthesis that Belleau was aiming for!

1. MeMgl 2.H 3 Q+

4.10.3 Mechanism The Fujimoto-Belleau reaction is a two-step one-pot transformation, which begins with a Grignard reaction (—>1). This is followed by a hydrogen shift tautomerisation, (8—>9), an aldol reaction, (9—>10), then loss of water through a reverse aldol (11—»12) resulting in the final product. H-shift BrMg'

Op

0 1

Aldol

Name Reactions for Carbocyclic Ring Formations

338

Reverse *Aldol

R° 10

11

Variations, Improvements and Modifications

4.10.4

Organometallic reagents other than Grignards can also be used to effect the Fujimoto-Belleau transformation. In their synthesis of the natural product (-)-nakamurol A, Bonjoch and co-workers used the lithium salt of dimethyl methylphosphonate to convert lactone 13 to the a,/?-unsaturated cyclic ketone 14.4 This procedure gave good yields (75% based on recovered starting material) and was a superior method to using methyllithium as a nucleophile. The use of methyllithium resulted in a methyl ketone, which then had to be subjected to an aldol reaction to obtain the desired product. 0^.0

.0

(MeO) 2 POCH 3 , BuLi 60%

13

14

An example of different substrates amenable to transformation in the Fujimoto-Belleau reaction is shown by the treatment of benzazepine 15 with radioactively labeled methylmagnesium iodide.5 This was followed by quenching with water to afford diketone 17. In this two-step procedure the diketone was isolated in 80% yield, then treated with base to give the final oc,/?-unsaturated enone 18. The synthesis illustrates the utility of the Fujimoto-Belleau reaction in the production of radiolabelled 3-benzazepines using labelled methyl iodide.

H,C

cr o

'-\

H20

*CH3Mgl Ph

*-

80% [14C] 64%

15 MgfJ

16

339

Chapter 4 Six-Membered Carbocycles

KOH, MeOH, H20 Ph

100% [14C] 94% 18

4.10.5 Synthetic Utility A relatively early example of the use of the Fujimoto reaction is illustrated by the work of Tournemine and co-workers.6 In their search for new antiandrogenes, the authors synthesised des-A-steroids 20 by treating lactones 19 with Grignard reagents. These and other analogues were then tested for their relative binding affinities at androgen receptors compared to that of testosterone. In some cases, the analogues were found to have comparable or lower affinity than testosterone itself. OAc

0 ^ 0

ΛΟΜΘ

TBSO^'^Y^Q

°-f 21

1. RCH2MgX 2. KOH, MeOH 3. H+

O (MeO)2P (MeO)2P(0)Me *n-BuLi, THF

TBSOx'

γ \ >

22

In their studies on mannose-derived carbocyclic sugars, Trabsa and co-workers applied a Wadsworth-Emmons modification of the FujimotoBelleau reaction to give a vinyl phosphonate rather than the expected enone. Originally this procedure was used as an alternative to the Ferrier cyclisation, which requires acidic conditions. However, the authors found that the formation of an enone or vinyl phosphonate depended on the carbohydrate stereochemistry. Lactone 21 gave the vinyl phosphonate 22 when treated

340

Name Reactions for Carbocyclic Ring Formations

with lithium dimethyl methylphosphonate while lactone 23 afforded enone 24 exclusively. OyO

,OMe

T T TBSO^S^S 0

o-

(MeO)2P(0)Me „.BULÌ.THF'

0

Y ^ l

TBSO^Y^O

23

24

4.11.6 Experimental 3-Hydroxy-4,6-substituted-3,3a,4,5,8,9,9a,9b-octahydro-l//aphthalen-7(2ii)-one 266 cyclopenta[a]naphthalen-7(2//)-one R1

25

0 A c

1- R2CH2Mg_X 2. KOH, MeOH 3. H+

26

To a solution of the enol lactone 25 (1 mmol) in anhydrous tetrahydrofuran (3 mL) was added the appropriate Grignard reagent (1.5 mmol) in ethereal solution at -60 °C over 30 min. After stirring at -60 °C for 1 h, the reaction mixture was poured onto saturated ammonium chloride solution, and the reaction product extracted with diethyl ether. The organic extract was washed and dried (sodium sulfate). After removal of the solvent, the residue was dissolved in 2 N methanolic potassium hydroxide solution (4 mL), and the resultant mixture heated under reflux for 1 h. The cooled mixture was neutralised with AcOH and evaporated under reduced pressure. The residue was then diluted with water and extracted with diethyl ether or dichloromethane. Chromatography of the crude product on silica gel (eluent 3:7 ethyl acetate/hexanes) afforded pure enones 26 in 20-50% yields. 4.10.7 References 1. 2. 3. 4. 5.

Turner, R. B. J. Am. Chem. Soc. 1950, 72, 579. Fujimoto, G. I. J Am. Chem. Soc. 1951, 73, 1856. Belleau, B. J. Am. Chem. Soc. 1951, 73, 5441-5443. Daz, S.; Cuesta, J.; Gozlez, A.; Bonjoch, J. J. Org. Chem. 2003, 68, 7400-7406. Heys, J. R.; Senderoff, S. G. J. Org. Chem. 1989, 54,4702^1706.

Chapter 4 Six-Membered Carbocycles 6. 7.

Morales-Alanis, H.; Brienne, M.-J.; Jacques, J.; Bouton, M.-M.; Nedelec, L.; Torelli, V.; Toumemine, C.J. Med. Chem. 1985, 28, 1796. Aloui, M.; Lygo, B.; Trabsa, H. Synlett 1994, 115.

341

342

Name Reactions for Carbocyclic Ring Formations

4.11 Haworth Reaction Richard J. Mullins and Everett W. Merling 4.11.1 Description The Haworth reaction is a classical method for the synthesis of tetralone, beginning with benzene and succinic anhydride. The three-step protocol involves a Friedel-Crafts acylation, followed by reduction of the arylketone, and an intramolecular Friedel-Crafts acylation. The tetralone analog may be further reduced and dehydrogenated to form new aromatic species, in what is known as the Haworth phenanthrene synthesis.

O ♦ù ^ ^^

b

3.H2S04

CO ä

4.11.2 Historical Perspective Although the modern Haworth reaction is more commonly used to form tetralone analogs, the reaction sequence first targeted the synthesis of phenanthrene and its derivatives. The original protocol used by Robert Downs Haworth in 1932 involved the reaction of naphthalene (1) with succinic anhydride (2) and aluminum chloride to form nearly equal quantities of naphthoylpropionic acids 3 and 4.

Formation of naphthoylpropionic acids 3 and 4 had been achieved in a similar manner by multiple groups between 1910 and 1920; however, there was a lack of sufficient documentation regarding yields, amounts of each isomer, and methods of separation at the time.2 Haworth was the first to separate the acids by using nitrobenzene instead of either carbon disulfide or benzene as a solvent in the reaction. The isolation of the individual acids 3 and 4 spawned a period of immense productivity for Haworth and coworkers, as these ketoacids were then used to form phenanthrene and

Chapter 4 Six-Membered Carbocycles

343

multiple derivatives of phenanthrene. Over the course of 2 years, Haworth published at least eight papers on the syntheses of phenanthrene derivatives. 714 Certainly, then, it is understandable why this reaction bears his name instead of those of the original discoverers. 4.11.3 Mechanism The Haworth synthesis consists of a Friedel-Crafts acylation of an aromatic ring with succinic anhydride and aluminum chloride, followed by the Clemmensen or Wolff-Kishner reduction of the resulting ketoacid. An intramolecular Friedel-Crafts acylation then results in the formation of tetralone or tetralone derivatives. Mechanistically, complexation of succinic anhydride (2) with AICI3 yields acylium ion 5, leading to the resonancestabilized cation 7 through nucleophilic attack by benzene (6). Deprotonation to rearomatize the ring is followed by hydrolysis resulting in the formation of ketoacid 8. Reduction of the ketone gives 9, setting the stage for a second Friedel-Crafts acylation via acylium ion 10 to afford tetralone (11).

o 11 4.11.4 Variations and Improvements The tetralone derivatives produced by the Haworth reaction are important synthetic intermediates. However, in Haworth's original work, his efforts were directed toward the synthesis of phenanthrene from naphthalene. Thus the synthesis of tetralone derivative 12 by the standard Haworth conditions is followed by a Clemmensen15"17 or Wolff-Kishner reduction18'19 of the ketone

Name Reactions for Carbocyclic Ring Formations

344

to give 13. Ruzicka's20'21 method, or other methods of dehydrogenation, then results in phenanthrene (14). In this review, when the sequence stops at the tetralone product, the reaction will be referred to as the Haworth reaction or Haworth tetralone synthesis; when these additional steps are used the process will be referred to as the Haworth phenanthrene synthesis. H2NNH2, KOH

Se or Pd/C

or Zn(Hg), HCI

A slight variation on the original Haworth conditions, which promotes the formation of the acylium ion for the intramolecular FriedelCrafts acylation is the conversion of the carboxylic acid into an acid chloride. The enhanced leaving group ability of the chloride ion allows milder conditions to be used in the final intramolecular acylation step. 4.11.5 Synthetic Utility Haworth tetralone synthesis The Haworth synthesis of tetralone derivatives has found substantial utility in natural product and small molecule synthesis. Zubaidha and co-workers performed the Haworth reaction on 2-methylanisole (15) to yield 18 as an intermediate in the synthesis of (±)-heritol (19), a potent itchthyotoxin.25 Beginning with 15, acylation to yield 16 is followed by the Clemmensen reduction to produce 17. Subsequent intramolecular Friedel-Crafts acylation results in the formation of tetralone 18. Ferraz and coworkers have also synthesized 18 in the same manner as an intermediate for the synthesis of (±)-mutisianthol (20), a potential antitumor agent.26'27 In addition, this substrate 18 has been used for the synthesis of various a-tetralols as substrates for enzymatic resolution studies.

;o

MeO

15

78

AlCh C 6 H 5 N0 2l 0 °C 80%

MeO

COOH

Chapter 4 Six-Membered Carbocycles

Zn(Hg),HCI

MeO

C 0 0 H

345

(CF 3 CO) 2 O,0°C i

M e 0

97%

Owing to the facile Friedel-Crafts reaction of electron-rich aromatic rings, methoxy-substituted benzene rings are viable substrates for the Haworth reaction. For example Wipf and Jung29 used the Haworth reaction with 21 in their formal synthesis of the natural product (+)-diepoxin σ, a fungal metabolite with antitumor properties. Following acylation to yield 22, Wolff-Kishner reduction resulted in the formation of 23, which underwent intramolecular acylation, providing 24 in high yield. Green and co-workers have also used the Haworth reaction successfully with polymethoxysubstituted benzyl rings.30 In addition, Swenton and Chen applied the Haworth reaction to synthesis of the 1,4-dimethoxytetralin ring system as a model for their studies on the effects of allylic substituents on the regiochemistry of bisketal hydrolysis.31 OMe

OMeO AICU

H 2 NNH 2 , NaOH

» triethylene glycol

C 6 H 5 N0 2 , rt 79%

OMe

22

OMe

O

61% OMe

85% H3PO4 P2O5 89%

In addition to tolerating substitution on the aromatic ring, the Haworth reaction proceeds with derivatives of succinic anhydride, allowing for broad substrate scope. Norlander and coworkers used an amide-

Name Reactions for Carbocyclic Ring Formations

346

substituted succinic anhydride reagent in the synthesis of 2-amino-6,7dihydroxy-l,2,3,4-tetrahydronaphthalene (ADTN), a powerful dopamine agonist.32 In this synthesis, acylation of 25 with substituted succinic anhydride 26 resulted in formation of 27. Triethylsilane reduction of 27 afforded 28 which was cyclized via a one-pot acid chloride synthesis/Friedel-Crafts acylation sequence to give 29. Melillo and coworkers similarly used an amide-substituted succinic anhydride derivative for synthesis of (7?,i?)-4-propyl-9-hydroxynaphthoxazine, another potent dopamine agnonist 33 O

H3CO

cr

H3CO»

H

3

y~CF3

'

25

CH2CI2

26

C O ^ A

Et,SiH

H 3 CO A ^So 2 C^ NH

CF 3 C0 2 H reflux

CF,

27

AICI,

NH

H

3C0

H3CO

28

72%

LPCI5, CH 2 CI 2

»

2. SnCI 4

H0 2 C

NH CF,

H3CO Η

3

0 Ο - ^ \ ^ Ν ^ CF, H

80%

29

In efforts toward the synthesis of aromatic ring-fused cyclic 1,2diketones, Ranu and Jana also made use of the Haworth reaction when anisole (30) and 31 were treated under Friede 1-Crafts conditions to produce 32. Subsequent reduction and cyclization produced 33 in good yield.34 O

O AICI3

MeO 30

CH 2 CI 2

^ ^ 31

°

90%

^MeQ.

347

Chapter 4 Six-Membered Carbocycles

1.H 2 NNH 2 , KOH (HOCH 2 ) 2 , 180 °C 2. PPA, 100 °C

MeO

70% „35

Clive and Wang's synthesis of the marine natural product hamigeran B (39), an inhibitor of polio and herpes viruses, uses a slightly modified Haworth reaction to convert w-cresol (34) into the tetralone derivative 38. Following acylation and reduction to yield 35, methylation of the phenolic oxygen produces 36. Methylation of the α-carbon to form 37 is followed by cyclization in the presence of POCI3, providing 38 in high yield. OH

34

O

J5

1. AICI3

OH

2. Zn, HgCI2 HCI, heat

35

OMe

Me 2 S0 4

COOH OMe

NaOH, Na 2 S 2 0 4

COOH

67% POCk CI2CHCHCI2 83%

The Haworth synthesis has also found substantial utility in materials synthesis. Within this area, Rheingold and co-workers were able to synthesize rigid spacer-chelators using a monobrominated tetralone prepared under modified Haworth conditions.36 Following para-acylation of bromobenzene (40) under vigorous conditions to yield 41, reduction under modified Wolff-Kishner conditions37 is followed by cyclization to give 42. O

Br

AICI3 o-CI 2 C 6 H 4 , 95 °C

40

85%

COOH

348

Name Reactions for Carbocyclic Ring Formations

1.H2NNH2, NaOH triethylene glycol 200 °C » 2. PPA, 90 °C, 2 h 93%

Levy and co-workers38 encountered a problem of selectivity when using the Haworth reaction to synthesize helical transition metal complexes. Although intermediate 51 seems well suited for synthesis via the Haworth procedure on anthracene (43), the keto acid obtained was predominately substituted at C-9 (in 44) rather than C-2 (in 45). The selectivity issue was creatively remedied using 9,10-dihydroanthracene (46) in lieu of anthracene (43), which then exclusively formed the acylation product 46. Following reduction of 47, the carboxylic acid 48 was necessarily esterified to 49 in order to avoid deactivation of the dehydrogenation catalyst. Dehydrogenation to 50 was then followed by an intramolecular Friedel-Crafts reaction to give 51 as a single regioisomer.

C02H

43

44 80%

O

4511%

C02H 2 H2NNH2-H20 3KOH »-

or 2 AICI3, 2 h, rt

(HOCH2CH2)20

61% 47

87%

Chapter 4 Six-Membered Carbocycles

349

C0 2 H H2S04, CH3OH diglyme reflux, 40 h 87%

98% 49 -C02Me CH3SO3H, 90 °C

% ) \

100%

Y \

)

51

50

Haworth phenanthrene synthesis Although not directly resulting in the synthesis of phenanthrene or its analogs, reactions, which can be classified under the Haworth phenanthrene synthesis have been widely exploited in synthetic endeavors,39 especially in the field of materials chemistry. For example, Ogino and co-workers have demonstrated an interesting way to form substituted pentacenes using the Haworth method.40 Replacing succinic anhydride with bisanhydride 53 in the Friedel-Crafts acylation of w-nonylbenzene (52) results in the formation of 54. Hydrogenation of the arylketones is followed by a second Friedel-Crafts acylation to produce 55. Finally, reduction with sodium borohydride and acidic workup results in the dehydrogenated product 56.

AlCh C9H19

52

pyridine (CICH2)2 40°C 34%

Name Reactions for Carbocyclic Ring Formations

350

HigCg,

^19^9 Ν

/°

H0 2 C \ _ )

Pd/C, THF C0 2 H

0=

H0 2 C

H2

CF3S03H

V.

56%

78%

»

C0 2 H \\

54

C9H19

C9H19

H19C9

H19C9

1.NaBH 4 (CH 3 OCH 2 CH 2 )20 ^ 2. HCI, H 2 0 52%

55

C9H19

56

°9,Ηι9

Rabinovitz and co-workers also used the Haworth phenanthrene synthesis to form complex fused aromatic ring systems.41 The bowl-like shape of corannulene 57 was extended through the acylation reaction with 58 to produce 59. Treatment of 59 with red phosphorus under strongly acidic conditions resulted in 60 in good yield.

COOH AICU CH 2 CI 2 70%

59

Chapter 4 Six-Membered Carbocycles

351

red phosphorus HI, AcOH, H20 reflux 72%

The Haworth phenanthrene synthesis has been extensively used in the synthesis of derivatives of chrysene, '4 an environmental pollutant which exhibits tumorigenic and mutagenic properties. For example Harvey and coworkers treated 61 with succinic anhydride under Friedel-Crafts conditions to produce 62.44 Reduction of the ketoacid under Wolff-Kishner conditions is followed by esterification to yield 63. Dehydrogenation of 63 is followed by saponification to yield carboxylic acid 64. Intramolecular Friedel-Crafts acylation produces tetralone derivative 65, which undergoes carbonyl reduction and dehydrogenation to produce 66. OMe

OMe H02C AICI3, CH2CI2 93%

1.H2NNH2,KOH (HOCH2)2 2. p-tolS03H MeOH 66%

Me02C ^.

OMe 1. 10%Pd/C trig ly me

*· 2. KOH, H20 EtOH 62% OMe

H02C

1.NaBH4 THF, EtOH 2. 10% Pd/C triglyme 62%

Name Reactions for Carbocyclic Ring Formations

352

The Haworth phenanthrene synthesis was also employed for the preparation of naphthalene intermediates toward the synthesis of novel HMG-CoA reductase inhibitors.45 The usual Haworth procedure was followed to secure tetralone 67. Hydride reduction of the carbonyl produced 68, which on dehydration to 69, was subsequently dehydrogenated with DDQ to provide naphthalene 70. A related procedure was used in the same work to replace the C-7 methyl with a chlorine atom.

Η0 9 α /CHo/k O 1.(CIOCI)2 CH2CI2

CH3

H02C

XH13

Zn, HCI

CH,

H3C

2. SnCI4 CH2CI2

67 CH3

OH R NaBH4

H3C

:

V

C H 3

EtOH

P205 Et,0

H

*-

3C

68 CH-,

DDQ

69 CH·,

nH3C

3

^OBz

toluene 70 CH3

4.11.6 Experimental OMe

OMeO AICI, .0

OMe

O

C6H5N02, rt 79%

OMe

22

O

Chapter 4 Six-Membered Carbocycles

353

4-(2',5'-Dimethoxyphenyl)-4-oxobutyric acid (22)29 To a solution of AICI3 (80.0 g, 0.60 mol) in nitrophenol (500 mL) were added at 0 °C succinic anhydride (30.02 g, 0.30 mol) and pdimethoxybenzene (37.31 g, 0.27 mol). The mixture was allowed to warm from 5 to 29 °C over a 3.5-h period, and the solution was then promptly poured into ice water. The organic layer was separated and extracted with 10% NaHCÜ3 solution. The combined aqueous layers were filtered and acidified to pH 1 by concentrated HC1 solution in an ice bath. The resulting very pale yellow solid was filtered and dried to afford 51 g (79%) of 22. OMe O

OMe H 2 NNH 2 , NaOH OH

OMe

22

O

triethylene glycol 61%

4-(2',5'-Dimethoxyphenyl)butyric acid (23) A solution of 22 (50.0 g, 0.21 mol) in triethylene glycol (620 mL) containing sodium hydroxide (31.6 g, 0.79 mol), hydrazine hydrate (26.5 g, 0.53 mol), and water (30 mL) was heated at reflux for 3 h and then heated further without a condenser until the temperature rose to 210 °C. After another hour, sufficient water was added to lower the temperature to 190 °C, and heating was continued for 4 h. The solution was then cooled, poured into a mixture of cone. HC1 and ice, and extracted with ether. The combined ether layers were dried (Na2SC>4) and concentrated in vacuo. Chromatography on S1O2 (hexanes/EtOAc, 2:1 -► 1:1) gave 28.7 g (61%) of 23 as a solid. OMe

OMe 85% H3PO4 P2O5 89%

5,8-Dimethoxy-3,4-dihydro-2H-naphthalen-l-one (24) To polyphosphoric acid prepared from 85% phosphoric acid (305 g) and P2O5 (278 g) was added 23 (14.0 g, 62.4 mmol). After the reaction mixture was stirred for 0.5 h at 80 °C, the resulting orange solution was poured into ice water and extracted with ether. The combined ether layers were washed with 1 N NaOH solution, dried (Na2SC>4), and concentrated in vacuo to afford 11.5 g (89%) of 24 as a pale yellow solid.

354

Name Reactions for Carbocyclic Ring Formations

4.11.7 References 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18. 19. 20. 22. 23. 24. 25. 26. 27. 28. 29. 30. 31. 32. 33. 34. 35. 36. 37. 38. 39. 40. 41. 42. 43.

Friedel, C; Crafts, J. M. Compt. Rend. 1877, 84, 1392, 1450. Giua, M. Rend. Soc. Chim. Ital. 1912, 9, 239. Giua, M. Ber. 1914, 47, 2115-2116. Borsche, W.; Sauemheimer, H. Ber. 1914, 47, 1645-1648. Krollpfeiffer, F.; Schäfer, W. Ber. 1923, 56, 620-632. Schroeter, G.; Müller, H.; Huang, J. Y. S. Ber. 1929, 62, 645-658. Haworth, R. D. J. Chem. Soc. 1932, 1125-1133. Haworth, R. D.; Letsky, B. M.; Mavin, C. R. J. Chem. Soc. 1932, 1784-1792. Haworth, R. D.; Bolam, F. M. J. Chem. Soc. 1932, 2248-2251. Haworth, R. D. J. Chem. Soc. 1932, 2717-2720. Haworth, R. D.; Mavin, C. R. J. Chem. Soc. 1932, 2720-2723. Haworth, R. D.; Mavin, C. R.; Sheldrick, G. J. Chem. Soc. 1934, 454-^161. Haworth, R. D.; Sheldrick, G. J. Chem. Soc. 1934, 864-867. Haworth, R. D.; Sheldrick, G. J. Chem. Soc. 1934, 1950-1952. Clemmensen, E. Ber. 1913, 46, 1837-1843. Clemmensen, E. Ber. 1914, 47, 51-63. Clemmensen, E. Ber. 1914, 47, 681-687. Kishner, N. J. Russ. Chem. Soc. 1911, 43, 582. Wolff, L. Liebigs Ann. Chem. 1912, 394, 86-108. Hanson, J. RMeyer, J. Helv. Chim. Ada 1921, 4, 505-510. Yang, T.; Huang, Y.; Cho, B. P. Chem. Res. Toxicol. 2006,19, 242-254. Diel, B. N.; Han, M.; Kole, P. L.; Boaz, D. B. J. Label. Compd. Radiopharm. 2007, 50, 551-553. Beland, F. A.; Churchwell, M. I.; Von Tungeln, L. S.; Chen, S.; Fu, P. P.; Culp, S. J.; Schoket, B.; Gyorffy, E.; Minàrovits, J.; Poirier, M. C; Bowman, E. D.; Weston, A.; Doerge, D. R. Chem. Res. Toxicol., 2005, 18, 1306-1315. Zubaidha, P. K.; Chavan, S. P.; Racheria, U. S.; Ayyangar, N. R. Tetrahedron 1991, 47, 5759-5768. Ferraz, H. M. C; Aguilar, A. M.; Silva, L. F. Tetrahedron 2003, 59, 5817-5821. Bianco, G. G.; Ferraz, H. M. C; Costa, A. M.; Costa-Lotufo, L. V.; Pessoa, C; de Moraes, M. O.; Schrems, M. G.; Pfaltz, A.; Silva, L. F. J. Org. Chem. 2009, 74, 2561-2566. Ferraz, H. M. C; Bianco, G. G.; Teixeira, C. C; Andrade, L. H.; Porto, A. L. M. Tetrahedron: Asymmetry 2007', 18, 1070-1076. Wipf, P.; Jung, J.-K. J. Org. Chem. 2000, 65, 6319-6337. Ameer, F.; Giles, R. G. F.; Green, I. R.; Pearce, R. Synth. Commun. 2004, 34, 1247-1258. Chen, C.-P.; Swenton, J. S. J. Org. Chem. 1985, 50, 4569^1576. Nordlander, J. E.; Payne, M. J.; Njoroge, F. G.; Vishwanath, V. M.; Han, G. R.; Laikos, G. D.; Balk, M. A. J. Org. Chem. 1985, 50, 3619-3622. Melillo, D. G.; Larsen, R. D.; Mathre, D. J.; Shukis, W. F.; Wood, A. W.; Colleluori, J. R. J. Org. Chem. 1987, 52, 5143-5150. Ranu, B. C; Jana, U. J. Org. Chem. 1999, 64, 6380-6386. Clive, D. L. J.; Wang, J. J. Org. Chem. 2004, 69, 2ΊΊΖ-Π%Α. Sommer, R. D.; Rheingold, A. L.; Goshe, A. J.; Bosnich, B. J. Am. Chem. Soc. 2001, 123, 3940-3952. Minion, H. J. Am. Chem. Soc. 1946, 68, 2487-2488. Wiznycia, A. V.; Desper, J.; Levy,'C. J. Dalton Trans. 2007,15, 1520-1527. Sekiguchi, S.; Hirai, M.; Ota, E.; Hiratsuka, H.; Mori, Y.; Tanaka, S. J. Org. Chem. 1985, 50, 5105-5108. Okamoto, K.; Kawamura, T.; Sone, M.; Ogino, K. Liq. Cryst. 2007, 34, 1001-1007. Aprahamian, I.; Preda, D. V.; Bancu, M.; Belanger, A. P.; Sheradsky, T.; Scott, L. T.; Rabinovitz, M. J. Org. Chem. 2006, 71, 290-298. Silveira, A.; McWhorter, E. J. J. Org. Chem. 1972, 37, 3687-3691. Mitra, A.; Biswas, T. K.; Ray, R. M. Tetrahedron 1992, 48, 10353-10362.

Chapter 4 Six-Membered Carbocycles

44. 45.

355

Dai, W.; Abu-Shqara, E.; Harvey, R. G. J. Org. Chem. 1995, 60,4905-4911. Prugh, J. D.; Alberts, A. W.; Deana, A. A.; Gilfillian, J. L.; Huff, J. W.; Smith, R. L.; Wiggins, J. M. J. Med. Chem. 1990, 33, 758-765.

Name Reactions for Carbocyclic Ring Formations

356

4.12

Moore Cyclization

Ewa Krawczyk and Roman Dembinski 4.12.1

Description

Moore cyclization is formulated as a cyclization of enyne-ketenes 1 to diradicale 2. This process usually proceeds by thermal induction, leading to the formation of a benzene ring.

"tt* 0*

Rs

Δ 1

Historical Perspective

4.12.2 MeO, MeO

2

S

-CH2OSiMe3

OSiMe3

138 °C p-xylene 80%

»

3 ♦ CH2OSiMe3

MeO

CH2OSiMe3

MeO

In 1985 Harold W. Moore and co-workers (University of California, Irvine), described the generation and chemistry of 2-alkenylethynyl ketenes, which were accessible from the corresponding alkynylcyclobutenones.1 For example, 4-alkynyl-4-trimethylsililoxycyclobutenone 3 forms an enyneketene 4. The conjugated ketene 4 undergoes ring closure to produce the diradicai 5 (or related zwitterion) which, in turn, proceeds to the substituted

Chapter 4 Six-Membered Carbocycles

357

1,4-benzoquinone 6. The reaction was carried out over 2 h under argon atmosphere in refluxing xylene. 4.12.3

Mechanism

Mechanistic and synthetic studies for the Moore reaction have been reviewed.2 Equilibrium between alkynylcyclobutenone and (2-alkynylethenyl)ketene 7 at elevated temperature has been assumed in the first mechanism. The enyne-ketene 7, in turn, undergoes ring closure with the formation of zwitterion intermediate 8. Finally, transfer of the substituent connected with one oxygen atom, to a negative site in the intermediate 8, gives 1,4-benzoquinone 9 as the product.1 Further studies by Moore et al. provided evidence that the quinone-forming rearrangement occurred via intramolecular migration of either the hydrogen atom or other group.3 The electronic nature of intermediate 8 was discussed and additional evidence for the intermediacy of the diradicai was presented. The stereoselective ring opening of alkynylcyclobutenones to 7 takes place under thermal conditions. Therefore, the electrocyclic ring opening affords the desired Z-isomer of (2alkynylethenyl)ketene 7. During the mechanistic studies on the thermal rearrangement of 4-alkynylcyclobuta-nones to 1,4-benzoquinones, Moore observed a competitive reaction leading, presumably via intermediate 10, to 2-alkylidene-1,3-cyclopentenediones ll. 1 '

C2-C7

R

0

0

YY

+or.<M E '

0 Y

s

9

-

R

)

R*J

rR ^E

0

R

C2-C6 +

or.O-E 10

o 11

358

Name Reactions for Carbocyclic Ring Formations

When the alkynyl moiety is substituted with an alkyl group or a proton only, the corresponding benzoquinones were detected as products of thermolysis. But when R = Ph, OR, or Me3Si, a mixture of both products was formed. Furthermore, the use of 4-alkynylcyclobutanones with electronwithdrawing substituents, like CC^Et or CH=CHOMe, resulted in the formation of cyclopentediones as a sole product. These results can be explained by the mechanism presented in the scheme above. Intermediate 10 is favored over intermediate 8 when substituent R better stabilizes the adjacent radical site.3 A ferrocenyl group at the alkyne also provides a stabilization that favors the formation of cyclopentene-l,3-diones.4 Computational investigations (ab initio methods for enyne-ketene 1 and substituent effects employing the DFT approach) of the regioselectivity of the cyclization of enyne-ketenes were carried out by Engels et al.5 For the core system 1 the C2-C7 cyclization proceeds via the most stable diradicai intermediate and is kinetically and thermodynamically favored with respect to C2-C6 cyclization. The cyclization modes for the enyne-ketenes are more endothermic but the substituent effects are more pronounced for the enyneallene (Myers-Saito cyclization). Substituents OMe at the C4 as well as OH at the C5 in the computed molecule core increase the contribution of the C 2 C6 cyclization by decreasing the free energy of activation, similar to the phenyl group attached at the alkynyl terminus (C7). A five-membered ring can be formed via the diradicai pathway, yielding the σ,π-diradical such as 10, or via a carbenelike intermediate (not illustrated).5 The computational comparison of various pathways of thermal reactions of an analog, in which a heteroatom replaces the central olefinic bond, with possible transformations of parent enyne-ketene 1, was carried out and showed little relevance.6 4.12.4

Variations and Improvements

Enediynyl ethyl ethers like 12 have been applied by Wang's group as precursors of enyne-ketenes 13, which underwent the Moore cyclization reaction to form diradicals. The intermediate 14 and (after 1,5-hydrogen shift) new diradicai 15, form, upon the cascade transformations, the final products: mainly chromanol 16 and spiro ketone 17. The latter is a result of subsequent intramolecular reaction of intermediates: o-quinones methide and spiro ketone (not illustrated).7

Chapter 4 Six-Membered Carbocycles

359 BLK

OEt

Et, O'

131 °C PhCI Bu'

Et 17(14%)

-H2C—CH2

Et

Et

Et

13

14

15

I Me(/

0 0

MeO

/^-Me | \ (DH Me

1. 138 °C, p-xylene 2. Ce(IV)/Si0 2 67%

MeO^ MeO""

^,Me v

Me

0 19

18

1 !

i\ MeO

MeO

MeO

MeO

Moore et al. investigated the thermal rearrangements of differently substituted cyclobutenones.8'9 Reactions of 4-alkenyl-4-hydroxycyclobutenones such as 18, in which the triple bond is replaced by a double bound, are complementary to the ring expansions of 4-alkynyl-4-hydroxycyclobutenones and provide a route to the differently substituted benzoquinones, such as aurrantiogliocladin 19. The reaction proceeds via enyne-ketene 20. Since cyclization produces a derivative of hydroquinone 21, an additional oxidation step is required that is accomplished with the use of cerium ammonium nitrate on silica.9 This ring expansion process is independent of the

Name Reactions for Carbocyclic Ring Formations

360

stereochemistry of the 4-alkenyl moiety. 4-Aryl-4-hydroxycyclobute-nones react also in a similar way which is exemplified in the Section 4.12.5. The thermal rearrangements of 4-substituted-3-methylenecyclobutenes (analogues of 4-alkynylcyclobutanones), leading to phenols, benzylidenecyclohexanones, or acyclic dienones, are discussed in the Chapter 4.13. Organometallic reagents were used for the synthesis of bicyclic aromatic compounds via Moore-type cyclization. Rahm and Wulff described the new synthesis of 5-hydroxyindolines with the use of a chromium carbene complex bearing alkynyl substituent 22.11 The amino-tethered bis-alkynyl carbene complex 22 was transformed into indoline 23 by thermolysis in the presence of a hydrogen source. The low yield of product 23 was improved when the reaction was carried out in the presence of the electrophile, added to protect the phenol function. This process involves the insertion of one carbon monoxide group from the chromium complex into the skeleton of an eneyne compound 24. The resulting enyne-ketene 25 undergoes a cycloaromatization reaction to afford the 1,4-diradical intermediate 26. Subsequent demetalation yields product 23."

0

THF, 80 °C

(100equiv), 25%

!-CO

Me^Cr(CO)4

Another example of the application of the chromium carbene complex for the synthesis of benzannulated compounds was described by Herndon and Wang.12 The coupling of substituted carbene chromium complex 27 with conjugated enediyne 28 results in the formation of intermediate enyne-ketene 29, which undergoes the Moore cyclization to produce the intermediate chromium-complexed diradicai 30. The

Chapter 4 Six-Membered Carbocycles

361

decomplexation converts 30 into product 31, which was identified from the postreaction mixture. In addition, these studies suggest that the chromium complexed diradicals may have alternative reactivity patterns as compared to analogous metal-free diradicals. MeO 100 °C

MeCL ^Me

dioxane

Cr(CO) 5 27

MeCL

»

31 (+ other products)

28

MeO^/Me

Me

.

(OC)3Cr

(OC)3Cr

29

30

1. 27, 100 °C

32

dioxane, 24 h 2. T s O H o r l 2 54%

a

34

MeO

(OC) 3 Cr—

33

Herndon et al. have investigated the reactions of Fischer carbene chromium complexes with conjugated enediynes that feature a pendant alkene group such as 32.13 The experimental results confirm that arene

362

Name Reactions for Carbocyclic Ring Formations

diradicals obtained via Moore cyclization undergo subsequent intramolecular radical cyclization reactions to neighboring alkenes. The latter reaction proceeds predominantly to diradicai 33 through the 6-endo cyclization mode ultimately giving rise to the highly substituted multicyclic benzofuran derivative 34. 4.12.5

Synthetic Utility

^E^CH 2 Ph 35

82 °C CH3CN 71%

LXxH2Ph !

MeO

I

♦

CH2Ph

CH2Ph

36

Since 4-alkynylcyclobutanones, precursors of enyne-ketene, are relatively readily available,1'14'15 subsequent transformation of enyne-ketenes to aromatic diradicals provide interesting synthetic opportunities. The synthetic utility of the Moore reaction can be illustrated by the efficient synthesis of coenzyme Qo (84%, not illustrated) or aurantiogliocladin 19 (described above, Chapter 4.12.4).9 The important application of 4-alkynyl-3-methoxy-4-hydroxycyclobutenones includes their ability to cleave supercoiled DNA by a mechanism that involves contribution from a diradicai intermediate. The 4-alkynyl-4hydroxycyclobutenones, which bear alkyl group at position 2 can effectively damage DNA, as opposed to the corresponding 2-alkoxy analogs (the latter could rearrange to their epoxides by a facile intramolecular pathway). For

Chapter 4 Six-Membered Carbocycles

363

example, the 2-[2-(9-antracenylthio)ethyl] derivative 35 and its 2-butyl analog effectively damaged DNA at 49 °C, presumably via diradicai intermediate 36. 16 Moore's group has also exploited his methodology for the synthesis of a variety of vV-heterocyclic quinones and hydroquinones such as piperidinoquinones 37, dihydrophenanthridinediols 38, benzophenanthridine 39, and assoanine 40, a member of a series of biologically active pyrrolophenanthridine alkaloids.17

Λ

^NS02Ph

RO

o

I"R 2

37 MeO, MeO

R MeO

38

39, benzophenanthridine

.0

•

OH

OH

138 °C p-xylene 40%

ft

NaH (EtO) 2 P(0)CI

Na/NH 3 25%

MeO MeO (EtO) 2 P(0)0

40, assoanine

Thermolysis of 4-hydroxycyclobutenone 41 offers an opportunity for the enantiospecific synthesis of pyranoquinone 42.18 The reaction proceeds via rearrangement of initially formed radical 43 to diradicai intermediate 44 that cyclizes in a stereopecific fashion.

Name Reactions for Carbocyclic Ring Formations

364 ROs 1 7

R 0

# "\

110 °C

OTIPS

9 H

(X

OH

toluene

1

OTIPS

OMe 41

42

t

OTIPS OMe 44 OMe O

OMe = ^

\

Me OTHP

138 °C

Me OTHP

p-xylene 71%

45 AcOH, THF I H 20, 72°/% OMeO

OMe O (T^S

Me

^ r " "OH

47 (R = Me) nanaomycin D

The Moore reaction is also effective for the synthesis of annulated derivatives of quinines. Moore et al. have established that 4-alkynyl cyclobutenones are precursors in the efficient syntheses of some members of the family of naturally occurring isochroman-l,4-naphthoquinones, which show biological activity as antibiotics and antymycotics.1 Benzocyclo-

Chapter 4 Six-Membered Carbocycles

365

butenedione has been used for the preparation of the corresponding 4-alkynyl benzocyclobutenones such as 45, which undergoes rearrangement to naphthoquinone 46 via diradicai cyclization under thermolytic conditions. Naphthoquinones such as 46 have been employed as key synthetic precursors to biologically important quinones: nanaomycin D 47 and deoxyfrenolicin (analog of 47 in which R = Pr).19 Since the C2-C6 cyclization is observed for the phenyl-substituted alkynylcyclobutenones, cyclization of 4-phenylethenyl derivatives provides an effective procedure. The cyclobutenone 48 was prepared from the 4phenyethynyl derivative by the Lindlar reduction and converted to benzoquinone 49 in a two-step procedure that includes oxidation. MeO. MeO

-v

O Ph J

1. 138 °C, p-xylene 2. K 2 C0 3 /Ag 2 0 71%

OH 48

1-lithiopropyne THF, 8 1 %

2-lithiopropene ether/THF, 72%

< OH Me

M e 0

51 1.C 6 H 6 , Δ, 2 h 2. Ce(IV), CH 2 CI 2

CH 3 CN 76% 82 °C

74% Me

O

Me

O

Me'

MeO

Y

Me

O 52, O-methylperezone

54, O-methylisoperezone

366

Name Reactions for Carbocyclic Ring Formations

The reaction of cyclobutenediones such as 50 with the appropriate alkenyllithium agent facilitates an alternative route to alkenyl butenones such as 51. 9 Further synthetic utility of the Moore reaction can be illustrated by the efficient parallel synthesis of (±)-0-methylperezone 52 and, proceeding from the alkynyl derivative 53, its regioisomer (±)-0-methylisoperezone 54.8'9 4-Aryl-4-hydroxycyclobutenones react similarly to 4-alkenyl-4hydroxycyclobutenones and provide a route to the differently substituted benzoquinones. Regiospecific synthesis of a series of hydroxyquinones and annulated derivatives was realized starting from di-i-butyl squarate (not illustrated) via 3-7-butoxycyclobutane-l,2-dione 55. Reaction of 55 with phenyllithium leads to aryl-substituted cyclobutanedione 56 that rearranges at elevated temperature to protected quinone 57. Deprotection of 57 yields natural product-lawsone 58, a component of henna dyes.20 Λ f-Buc/

V0

X

^

LPhLi 2NH

4CI

f-BuO'

55

OH

56 82 °C I CH3CN

63%

i-BuO'

4.12.6

CF3COOH quantitative

f-BuO

Experimental

Moore thermal cyclization of 2,3-dimethoxy-4-(3-trimethylsilyl-lpropynyl)-4-trimethylsiloxycyclobut-2-en-l-one (59): 2,3-dimethoxy-5\21 trimethylsilyl-6-((trimethylsilyl)-methyl)-l,4-benzoqui-none (60) MeO. MeO

O

S

—

OSiMe3 59

SiMe-i

/

138 °C p-xylene, 65%

SiMe3

MeO y\eO

SiMeq

Chapter 4 Six-Membered Carbocycles

367

A solution of cyclobutenone 59 (0.297 g, 0.910 mmol) in anhydrous p-xylene (60 mL) was heated at reflux for 1 h. Concentration in vacuo followed by flash column chromatography on silica gel (hexanes/ethyl acetate, 10 : 1) gave 60 (0.190 g, 0.582 mmol, 65%) as an orange oil. Moore thermal cyclization of yV-benzhydryl-./V-[3-(l-hydroxy-2,3-diisopropoxy-4-oxocyclobut-2-enyl)prop-2-ynyl]-3-phenylacrylamide(61): 2-benzhydryl-4-benzyl-6,7-diisopropoxy-l,4-dihydro-2i/-isoquinoline3,5,8-trione (62).22 /-PrO.

.0 xylenes

/-PrO

\

N

OH

N_y

Ph-^

61

Ph Ph

Δ, 65%

·

62

A solution of the cyclobutenone 61 (0.3100 g, 0.5640 mmol) in freshly degassed xylenes (10 mL) was added dropwise over a 20-min period to refluxing, degassed xylenes (40 mL). After the addition was complete, the reaction mixture was cooled to room temperature and concentrated in vacuo. The resulting red oil was purified by column chromatography on S1O2 (hexanes/ethyl acetate/dichloromethane 6:1:3) to afford isoquinolinone 62 (0.2077 g, 0.3779 mmol, 67%) as a red oil. 4.12.7 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14.

References Karlsson, J. O.; Nguyen, N. V.; Foland, L. D.; Moore, H. W. J. Am. Chem. Soc. 1985,107, 3392-3393. [R] Wang, K. K. Chem. Rev. 1996, 96, 207-222. Foland, L. D.; Karlsson, J. O.; Perri, S. T.; Schwabe, R.; Xu, S. L.; Patii, S.; Moore, H. W. J. Am. Chem. Soc. 1989, 111, 975-989. Zora, M.; Kokturk, M.; Eralp, T. Tetrahedron 2006, 62, 10344-10351. Musch, P. W.; Remenyi, C; Helten, H.; Engels, B. J. Am. Chem. Soc. 2002, 124, 1823-1828. Schreiner, P. R.; Bui, B. H. Eur. J. Org. Chem. 2006, 1162-1165. Tarli, A.; Wang, K. K. J. Org. Chem. 1997, 62, 8841-8847. Perri, S. T.; Dyke, H. J.; Moore, H. W. J. Org. Chem. 1989, 54, 2032-2034. Perri, S. T.; Moore, H. W. J. Am. Chem. Soc. 1990,112, 1897-1905. Ezcurra, J. E.; Pham, C; Moore, H. W. J. Org. Chem. 1992, 57, 4787-4789. Rahm, A.; Wulff, W. D. J. Am. Chem. Soc. 1996,118, 1807-1808. Herndon, J. W.; Wang, H. J. Org. Chem. 1998, 63, 4562-4563. Zhang, Y.; Irshaidat, T.; Wang, H.; Waynant, K. V.; Wang, H.; Herndon, J. W. J. Organomet. Chem. 2008, 693, 3337-3345. Nakatani, K.; Isoe, S.; Maekawa, S.; Saito, I. Tetrahedron Lett. 1994, 35, 605-608.

368 15. 16. 17. 18. 19. 20. 21. 22.

Name Reactions for Carbocyclic Ring Formations Chow, K.; Moore, H. W. J. Org. Chem. 1990, 55, 370-372. Sullivan, R. W.; Coghlan, V. M.; Munk, S. A.; Reed, M. W.; Moore, H. W. J. Org. Chem. 1994, 59,2276-2278. Xiong, Y.; Moore, H. W. J. Org. Chem. 1996, 61, 9168-9177. Xiong, Y.; Xia, H.; Moore, H. W. J. Org. Chem. 1995, 60, 6460-6467. Foland, L. D.; Decker, O. H. W.; Moore, H. W. J. Am. Chem. Soc. 1989, 111, 989995. Heerding, J. M.; Moore, H. W. J. Org. Chem. 1991, 56,4048-4050. Ezcurra, J. E.; Karabelas, K.; Moore, H. W. Tetrahedron 2005, 61, 275-286. Wipf, P.; Hopkins, C. R. J. Org. Chem. 1999, 64, 6881-6887.

Chapter 4 Six-Membered Carbocycles

4.13

369

M y e r s - S a i t o Cyclization

Ewa Krawczyk and Roman Dembinski 4.13.1

Description

The Myers-Saito cyclization is formulated as a cyclization of enyne-allenes 1 to diradicale 2. It usually proceeds by thermal induction and leads to the formation of a benzene ring. R1

R

^AR2 \

R R3

R

Δ

^ 1

1

.R 2

I if r Jl k.

R3

2

4.13.2 Historical Perspective The Myers-Saito cyclization was first described independently in 1989 by Isao Saito1 (Kyoto University, Japan) and Andrew G. Myers2 (California Institute of Technology, Pasadena) whose findings were submitted for publication on June 7 and June 12, respectively. As a parallel transformation to the Moore cyclization (Chapter 4.12), in which an allenic fragment replaces the ketene moiety in the substrate, the Myers-Saito reaction provides a path to carbon diradicate.1-5 In its pioneering version, the reaction involved the cyclization of (Z)-l,2,4-heptatrien-6-yne (enyne-allene) 3, 2 ' 4 or its phosphine oxide derivative 5,1'3 to substituted oc,3-dehydrotoluene diradicals, and subsequently to toluene derivatives 4 and 6. The reaction proceeds under thermal neutral conditions in 1,4-cyclohexadiene or other organic solvents such as methanol or carbon tetrachloride. Myers CH2OCD3 CD3OH Δ, 70% 3

1

4

Name Reactions for Carbocyclic Ring Formations

370

Sa ito 11

Ph >P~.

O

χί^

, ^ Ή

Ph

(CH 2 ) 2 OAc

CH 3

2P\/^/(CH2)2OAc

37 °C, 5 h 32%

4.133

Mechanism

From a mechanistic point of view, in the initial step, the (Z)-l,2,4-heptatrien6-yne, or compounds containing an equivalently unsaturated core, undergoes a mild, thermal electrocyclization reaction to form an oc,3-alkylbenzenediyl, a diradicai intermediate with substantial polar character. Dehydroaromatic intermediate 7, when trapped by the solvent or compounds (e.g., 1,4cyclohexadiene) present in the reaction medium, forms than aromatic products of type 8, 9, and 10.6 In methanol, a mixture of hydrogen atom abstraction and polar addition product are obtained.2

H^.M

9

(55%, 1:1) 10

Extensive mechanistic studies of this cyclization reaction were carried out by Myers et al.6 and extended with theoretical work by Squire's et al.7'8 It is known that, in contrast to the Bergman cyclization of the ene-diyne (Chapter 4.2), this transformation proceeds as an exothermic process determined by the increased stability of a benzyl radical versus a phenyl radical. The barrier for cyclization from substrate to a diradicai product is low and can further be reduced by an appropriate substitution at the allenic terminus of the substrate.6 The dichotomous (polar and free radical) reactivity is observed on pyrolysis in the presence of polar reactants. Both radical and polar products arise from a common intermediate, which is described as a "polar diradicai," a linear combination of limiting structure 7 and zwitterion ll. 9 According to Squires, "polar diradicai" singlet species are involved.8 Based on computational studies supported by experimental product distribution studies, it has been proposed that both the diradicai 7 and

Chapter 4 Six-Membered Carbocycles

371

zwitterionic 11 forms are produced from the common cyclization transition state by a transition to the zwitterion, which is the excited state of the diradicai.10'11

11 The investigation of various parameters of the cyclization of enyneallene 12, using the density functional theory (DFT), has been undertaken.12'13 This includes the thermodynamics for both C2-C7 (leading to 13) and C2-C6 (leading to 14 and called Schmittel reaction) reaction pathways. Theoretical calculations address the regioselectivity of diradicai cyclization in enyne-allene with a different substitution. This study rationalizes the switch between the two radical cyclizations (C2-C7 vs. C 2 C6) on the basis of mainly steric (12, R = ί-Bu) or electronic effects (R = Ph) of substituents at the alkyne terminus.13

C2-C7

C2-C6

12

13

14

Lipton et al. noticed that the switching of cyclization pathways observed by Schmittel takes place due to a combination of effects. The calculations of the energies of diradicals formed by Myers-Saito and Schmittel cyclization indicate that benzannulation of the eneyne-allene as in 15 plays a significant role in promoting C2-C6 cyclization. The energy of diradicals for the benzannulated system is 10.5 kcal/mol less as compared to those for the parent monocyclic diradicals (16 vs. 13, and 17 vs. 14). n FL..-R 1 ,R"

16

C2-C7

C2-C6

15

17

372

Name Reactions for Carbocyclic Ring Formations

Studies of the diradicai (stabilized by a phenyl group) or zwitterionic intermediate have been undertaken for the Schmittel reaction of the enyneallene with larger substituents (SiMe3, /-Bu). It was reported that C2-C6 cyclization occurs via the diradicai intermediate and aryl or bulky groups at the alkyne terminus trigger a general thermal reaction pathway for the enyne-allene.14 Substitution at the terminus of the allenic moiety, as well as at the terminus of the acetylenic moiety, influences the rate of cyclization. Introduction of one or two methyl groups (12, R,R! = Me) at the allenic moiety accelerates the reaction rate, ' whereas substitution at the alkyne terminus usually reduces the reaction rate.15 Thermal reactions of enyne-allenes initiated by employing different modes such as base,16 acid,17 and light18'19 have also been investigated. 4.13.4

Variations and Improvements

Competition between the Myers-Saito and Schmittel cyclization is also observed for phosphorus-substituted allenes. Terminal alkynes 18 give naphthalene derivatives 19. Ph2PO

toluene 50 °C, t1/2 ~ 1 h 57% 18

19

When an aromatic substituent is bound to the alkyne terminus, as illustrated for the terminal alkyne 20, a competitive, thermally initiated C 2 C6 cyclization of an enyne-allene takes place. This process gives indene derivatives such as 21. 20 ' '

o

toluene 84 °C, t1/2 ~ 1 h 76% 20

Ph2P(0)

Chapter 4 Six-Membered Carbocycles

373

The photochemical cyclization of the Myers-Saito and Schmittel cyclization of enyne was described much later than the Bergman photochemical variant.18 The theoretical studies indicate that this process is initiated by triplet sensitization.19 The investigation was carried out using a series of enyne-allenes containing an internal triplet sensitizer unit attached to an aliene terminus. The irradiation of enyne-allene containing a biphenyl group 22 at 300 nm in the presence of 1,4-cyclohexadiene resulted in the formation of photocyclization products: Myers-Saito (C2-C7) tetrahydronaphthalene derivative 23 and Schmittel (C2-C6) multicyclic product 24.

22

23(24%)

24(12%)

For the case of oxyanion, two factors were found to play a role. The size and nature of the ring in which enyne-allene is embedded as well as the steric bulk of the substituents of the aliene and alkyne affects the competition between the two cyclizations. The Myers-Saito product is not observed for alkynes with the trimethylsilyl substituent even for cyclohexane-annulated compounds. However, when the alkynyl substituent is changed to phenyl, the resulting relief of steric strain in the C2-C7 transition state permits the cyclization of 25 to occur at low temperature and yields the styrene derivative 26.22 The cyclopentane-annulated compounds give the MyersSaito product, or fail to react when a bulky silyl substituent is present at the alkynyl terminus. In contrary, the benzene-annulated compounds undergo rapid the Schmittel cyclization dominantly or exclusively. The cyclizations of oxyanion-substituted enyne-allenes studied in the cited article occured at far lower temperatures than the analogous cyclizations of neutral enyneallenes.22 The presence of the oxyanion presumably stabilizes, by resonance, the diradicai in the transition state.22"24

Name Reactions for Carbocyclic Ring Formations

374

TMS AcO

MeLi toluene,-10 °C 93% 26

25

However, for the cyclization of the oxyanion substituted enyneallene, substitution causes both the Myers-Saito and Schmittel cyclizations to switch their product formation preferences from diradicals to polar intermediates, as established by DFT.22'24 The stabilization of the oxyanionderived Schmittel products is greater than those of the Myers-Saito reaction.24 Cyclic 10- and 11-membered ring enediynes, functionalized by a carbonyl group in the ß position with respect to the acetylenic terminus, undergo facile cycloaromatization at ambient temperature. Kinetic data and deuterium labeling experiments indicate that cyclization proceeds via a ratedetermining tautomerization into a more reactive enyne-allene such as 27. This tautomer undergoes Myers-Saito cyclization via diradicai 28 to give tricyclic product 29. The process of cycloaromatization exhibits the strong effect of general base catalysis.16

/-PrOD

27

28

29

It is interesting that when the enyne-allene moiety is incorporated into a bicyclic system, such as [7.3.2]-eneyne-allene 30, cyclization does not proceed. In contrast, the Bergmann cycloaromatization has been observed for a related substrate, [7.4.1]-enediyne (not illustrated).25

Chapter 4 Six-Membered Carbocycles

375

30

Nonconjugated diynes of the type 31 may rearrange to generate enyne-allene 32, which undergoes Myers-Saito cyclization. When the sulphur-substituted 10-membered ring of l,6-diyn-3-ene 31 is treated with DBU under aerobic conditions, the compounds 33-36 are produced from the diradicai intermediate 37. Anaerobic conditions yield compounds 33 (10%), 34 (19%) and 35 (5%). It has been suggested that the rather stable cyclic diyn-ene 31 under basic conditions undergoes the propargylic rearrangement to 32 to form in turn the intermediate 37. 6 Selenium(IV) oxide (SeÜ2) can also facilitate the cycloaromatization of 31 combined with an oxidation. The reaction proceeds via an enyne-allene seleninic acid radical intermediate which subsequently indergoes cyclization to produce isothiochroman-4-one 36 along with an analog in which R = H.27

31

33(8%)

32

34(8%)

35(4%)

36 (R = CI, 12%)

Cumulene structures also undergo the Myers-Saito reaction. Cyclization of acyclic enyne[3]cumulenes, on the activation of Z-configured dienediyne 38 via acid solvolysis, has been described by Bruckner et al.17 It has been found that 38 dissolved in /-BuSH/dichloro-methane and treated with a catalytic amount of triflic acid forms the monocyclic cumulene 39. Storage of the mixture for 4 days at room temperature gave the corresponding styrene derivatives 40 and 41; these products form as a result of cycloaromatization via path A (benzoid radical). Independently, after

Name Reactions for Carbocyclic Ring Formations

376

purification of 39, compound 42, formed by path B cyclization via a quinoid σ,σ-diradical, was detected.

SiMe-j

38

CF3SO3H cat. f-BuSH/CH 2 CI 2

f-BuS

Et 3 N, - 6 5 °C ' 15 min, ~46%

39

f-BuS f-BuS SiMe·, SiMe 3 benzoici

quinoid

Ph

f-BuS Ph

f-BuS

SiMe 3 S-i-Bu 40 (4%)

41(2%)

"SiMe 3 42(10%)

The cyclic cumulene structures were investigated. The 1,6didehydro[10]annulene 43, was prepared and characterized spectroscopically at -90 °C by Myers and Finney.2 This compound undergoes cyclization rapidly at -60 °C to form a localized σ,σ-diradical intermediate 44, which leads to naphthalene. The kinetics for the cyclization reaction, in CD2CI2 in the presence of 1,4-cyclohexadiene, is found to be first order. Isotope incorporation takes place from a deuterated solvent and yields 1,5dideuterionaphthalene 45.

377

Chapter 4 Six-Membered Carbocycles

t-i/2 ~ 25 min

e.g., THF-d 8

- 5 1 °C

50-85%

i

43

44

45

Myers et al. treated the epoxy dienediyne 46 with methyl thioglycolate and triethylamine. The isomerie naphthalene derivatives 47 and 48 were produced as a result of the transformation involving diradicai precursors formed from the l,6-didehydro[10]annulene intermediate 49 via route A and B.29 Compounds 47 and 48, with indicated levels of deuterium incorporation, were also formed when the experiment was conducted in a deuterated solvent. OTBS OSO,Me

Et

JBSO

OTBS HSCH2CQ2Me 3 N · DMSO/THF* TBSQ

SCH2C02Me 49

46

Α

Γ

B

(39% D) H

OTBS

(39% D) H

TBSO"<( Jj TBSÖ

H (10% D) "SCH2C02Me (60% D) 47 (67%)

Me02CCH2S

I

OH

T /"'OTBS

H (27% D)

48 (20%)

An aza-variant of the cycloaromatization of propargyl azaeneynes, such as 50, via azaenyne-allenes 51, has been reported by Kerwin et al.30 The aza-Myers-Saito cyclization provides a,5-didehydro-3-picoline diradicai 52, which affords either polar or radical-based trapping products 53 and 54, depending on the reaction solvent. The facility of the aza-Myers-Saito cyclization relative to the parent Myers-Saito cyclization was predicted based on DFT calculations; these results also indicate that the corresponding C2-C6 (aza-Schmittel) cyclization, although disfavored in the case of 51, is

378

Name Reactions for Carbocyclic Ring Formations

more competitive with the aza-Myers-Saito cyclization than the case with enyne-allenes.

Ph

Ph 53(17%)

Ph 54(20%)

These studies were extended for the synthesis and DNA cleavage chemistry of pyridinium aza-enediynes (2-alkynyl-iV-propargyl pyridinium salts).31 The 2-alkynyl-./V-propropargyl pyridinium trillate 55 cleaves DNA by hydrogen atom abstraction from the deoxyribose backbone, presumably through the intermediacy of diradicals formed by either aza-Myers-Saito or aza-Schmittel cyclization. Attempts to identify trapping products of these intermediates were unsuccessful.31

4.13.5

Synthetic Utility

The thermal rearrangements of 4-substituted-3-methylenecyclobutenes, which are analogs of 4-substituted-4-hydroxycyclobuten-3-ones (substrates

Chapter 4 Six-Membered Carbocycles

379

for the Moore reaction, Section 4.12.4), were investigated. The ring expansions of 4-alkynyl-3-methylenecyclobutene 56 provide a route to the differently substituted phenols such as 57 and 58.32 Ph Me, Ph

-Bu OH

140 °C p-xylene

»

49 h 65%

56

MeO^/Ph

Me^J\^Bu P h ^ OH

MeOH

Me

38 h 42%

Ph

58

When the analog in which a double bond replaces the triple bond (4alkenyl-3-methylenecyclobutene 59) is used, the benzylidenecyclohexanone 60 is obtained. These ring expansion processes represent potentially useful synthetic transformations.3 Ph Me. Ph

I

//

cDH 59 i

138 °C p-xylene 81%

Me^

o V

Ph""

0 60 i

OH

380

Name Reactions for Carbocyclic Ring Formations

Using the 1,6-addition of lithium dimethylcuprate to dienediynes with an endocyclic double bond 61, Krause and Hohmann have synthesized the corresponding acceptor-substituted enyne-allenes 62. These allenes undergo Myers-Saito cyclization to diradicals 63, which react by intramolecular hydrogen migration to yield the α,β-unsaturated ester 64 (R1 = t-Bu, R2 = H). It was found that a compound containing two methyl groups at C-2' gives, as the cyclization product, the decaline derivative 65 (R1 = Pr, R2 = Me) by intermolecular hydrogen abstraction from the solvent. 3 C02Et C02Et 1

1. Me2CuLi'Lil 2. R2X

*

50 °C, 4 h 1

2

R1 = Pr, R2 = Me

R = f-Bu, R = H C02Et

~O02Et f-Bu

64 (43%)

65

Wang's group investigated the application of the diradicals generated from enyne-allenes for the cascade radical cyclizations allowing for the synthesis of various tetracyclic ring systems.5'15 Among them, the construction of the tetracyclic steroidal skeleton having an aromatic C-ring was realized.34 Acyclic enyne-allene 66 bearing 3-butenyl and 7-hexenyl substituents served as a substrate. Its thermal cyclization probably proceeds via intramolecular trapping of a diradicai by the carbon-carbon double bond and subsequent 1,5-hydrogen shift to form o-quinodimethane 67. This transformation yields the tetracyclic system having the trans ring junction 68.

Chapter 4 Six-Membered Carbocycles

381

,Me

50% 67

68

The transition metal catalysis of the Myers-Saito cyclization of enyne-allenes has been investigated. Molybdenum-mediated carbonylation of l-ethynyl-2-allenylbenzenes occasionally gave minor by products derived from the Myers-Saito rearrangement (not illustrated).35 Toste's group elaborated an effective synthetic route to aromatic ketones via a transition metal-catalyzed tandem [3,3]-sigmatropic rearrangement/Myers-Saito cyclization of propargyl esters such as 69.36 In this method the required enyne-allenes 70 were prepared in situ via a metal-catalyzed sigmatropic rearrangement; following the diradicai cyclization at room temperature to afford differently substituted aromatic ketones, such as 71, in high yield. OPiv AgSbF6 (5 mol%) PPh3 (2 mol%)

PivO

69

MgO (1.5equiv) CH2CI2, rt, 11 h 83%

»

70

71

In many cases the silver(I)-catalyzed naphthyl ketone synthesis proceeds as well or better than the analogous gold(I)-catalyzed reaction. However, attempts at silver(I)-catalyzed rearrangement of pyrrole 72 failed to produce the desired aromatic ketone. In this case, the analogous tri-/-

Name Reactions for Carbocyclic Ring Formations

382

36 butylphosphine-gold(I)-catalyzed reactions delivered indole 73/° A mechanism, in which the metal catalyzes the rearrangement and cyclization process through alkyne activation, was proposed. Both silver and gold procedures are tolerant to air and moisture.

i-Bu3PAuCI (5 mol%) AgSbF6 (5 mol%) CH2CI2/CH3CN rt, 10 h 58% 72

TsN 73

The presence of a cyclic enediyne fragment in antitumor antibiotics initiated a wide interest in application of this reaction for DNA cleaving studies. Neocarzinostatin chromophore, a nonprotein component of the antitumor antibiotic, consists of a diene-diyne structural fragment embeded in a nine-membered ring and forms species capable of cleaving DNA upon activation with thiol. The structure of this species was established as enyne[3]cumulene. The mechanisms of the conversion of analogs of neocarzinostatin chromophore such as 74 involving formation of an enyneallene intermediate such as 75 were proposed and are exemplified for the ketone analog under anaerobic conditions.37 Another neocarzinostatin chromophore-related model study is described in Section 4.13.3 (compounds 46-49).

\

_ 74

75 RS*

RS

^SR

Chapter 4 Six-Membered Carbocycles

383

Due to the lower activation energy for the Myers-Saito cyclization versus the Bergman cyclization, even simple, acyclic enyne-allenes can generate diradicai intermediates under physiological conditions. Thus the enyne allenes 76 and 77 cleave supercoiled plasmid DNA at 37 °C, pH 8 (phosphorus compounds appeared to be more suitable for practical studies of antitumor activity or DNA-cleaving properties than the corresponding sulfur compounds). It is interesting that products of cleavage activity toward both double-strand and single-strand DNA were observed. However, in general, due to differences in radical character, double-strand DNA cleavage, analogous to that observed for enediynes, would not be expected from enyne-allenes. Another simple, acyclic enyne aliene 78, and its conjugate with the DNA minor groove binding element derived from distamycin A (not illustrated) also displays DNA cleavage activity.38 The cleavage pattern and kinetics support a mechanism involving hydrogen atom abstraction by the Myers-Saito cyclization-derived diradicai, although no details of the DNA cleavage products, indicating the site of hydrogen atom abstraction were reported. Efforts in the area of DNA damage studies via diradical-generating cyclizations was recently reviewed by Kerwin.39'40 OAc 76 R = P(0)Ph2 77 R = S(0)Ph

78

Outline of an DNA initial interaction with phosphorus-substituted enyne-allenes is exemplified below.41 Ph2PO R2

DNA-Nu:

© OPPh2 DNA-Nu

PhzPCO^R! ( DNA cleavage)

384

Name Reactions for Carbocyclic Ring Formations

4.13.6 Experimental Allene-enyne thermal Myers-Saito cyclization of [(4Z)-S-tertbutyldimethylsilyloxy-l-(teri-butyldimethylsilyloxymethyl)octa-l,2,4trien-6-yn-l-yl](diphenyl)phosphine oxide (79): {2- teri-butyldimethylsilyloxy-l-[2-(fóri-butyldimethylsilyloxymethyl)phenyl]ethyl}(diphenyl)phosphine oxide (80)41 Ph2PO

Ph2P(0) .OTBS OTBS

79

37 °C, 16 h 60%

80

Compound 79 was obtained from the corresponding propargylic derivative (1 equiv) by treatment with diphenylphosphine chloride (1 equiv) in dichloromethane solution at -78 °C for 1 h, in the presence of triethylamine (1 equiv). After [2,3]-sigmatropic rearrangement, the reaction mixture was heated at 37 °C in the presence of cyclohexadiene (0.01 M) for 16 h, (tm = 8 h) to give the corresponding phosphine oxide toluene derivative 80 in 60% yield. Silver(I)-catalyzed [3,3]-Sigmatropic rearrangement and Myers-Saito cyclization of l-(2-Ethynylphenyl)hept-2-yn-l-yl pivalate (69): l-(2Naphthyl)pentan-l-one (71)36 A small screw-cap scintillation vial equipped with a magnetic stir bar was charged with AgSbF6 (5 mol %), triphenylphosphine (2 mol %), MgO (1.5 equiv), and dichloromethane. A solution of propargyl ester 69 (~ 150 mg, 1 equiv) in dichloromethane was added to the cloudy white suspension. The reaction mixture was stirred at room temperature and monitored periodically by TLC. Upon completion, the reaction mixture was loaded directly onto a silica gel column. Flash chromatography (hexanes/ether 19:1) gave the naphthlyl butyl ketone 71 as a light brown solid (83%). 4.13.7 References 1. 2. 3. 4. 5. 6. 7.

Nagata, R.; Yamanaka, H.; Okazaki, E.; Saito, I. Tetrahedron Lett. 1989, 30,4995^998. Myers, A. G.; Kuo, E. Y.; Finney, N. S. J. Am. Chem. Soc. 1989, 111, 8057-8059. Nagata, R.; Yamanaka, H.; Murahashi, E.; Saito, I. Tetrahedron Lett. 1990, 31, 2907-2910. Myers, A. G.; Dragovich, P. S. J. Am. Chem. Soc. 1989, 111, 9130-9132. [R] Wang, K. K. Chem. Rev. 1996, 96, 207-222. Myers, A. G.; Dragovich, P. S.; Kuo, E. Y. J. Am. Chem. Soc. 1992, 114, 9369-9386. Wenthold, P. G. ; Paulino, J. A.; Squires, R. R. J. Am. Chem. Soc. 1991,113, 7414-7415.

Chapter 4 Six-Membered Carbocycles 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18. 19. 20. 21. 22. 23. 24. 25. 26. 27. 28. 29. 30. 31. 32. 33. 34. 35. 36. 37. 38. 39. 40. 41.

385

Wenthold, P. G.; Wierschke, S. G.; Nash, J. J.; Squires, R. R. J. Am. Chem. Soc. 1993, 115, 12611-12612 and J. Am. Chem. Soc. 1994, 116, 4529 (erratum). [R] Salem, L.; Rowland, C. Angew. Chem., Int. Ed. 1972,11, 92-111. Cremeens, M. E.; Hughes, T. S.; Carpenter, B. K. J. Am. Chem. Soc. 2005,127, 6652-6661. [R] Carpenter, B. K. Chem. Soc. Rev. 2006, 35, 736-747. Wenthold, P. G.; Lipton, M. A. J. Am. Chem. Soc. 2000,122, 9265-9270. Engels, B.; Lennartz, Ch.; Hanrath, M.; Schmittel, M.; Strittmatter, M. Angew. Chem., Int. Ed. 1998,57, 1960-1962. Schmittel, M.; Kiau, S.; Siebert, T.; Strittmatter, M. Tetrahedron Lett. 1996, 367, 7691-7694. Andemichael, Y. W.; Gu, Y. G.; Wang, K. K. J. Org. Chem. 1992, 57, 794-796. Karpov, G.; Kuzmin, A.; Popik, V. V. J. Am. Chem. Soc. 2008,130, 11771-11777. Scheuplein, S. W.; Machinek, R.; Suffert, J.; Bruckner, R. Tetrahedron Lett. 1993, 34, 65496552. Schmittel, M.; Mahajan, A. A.; Bucher, G. J. Am. Chem. Soc. 2005, 127, 5324-5325. Spöler, C; Engels, B. Chem. Eur. J. 2003, 9,4670-4677. Schmittel, M; Wohrle, C. Tetrahedron Lett. 1993, 34, 8431-8434. Schmittel, M.; Strittmatter, M.; Kiau, S. Tetrahedron Lett. 1995, 36,4975^1978. Waddell, M. K.; Bekele, T.; Lipton, M. A. J. Org. Chem. 2006, 77, 8372-8377. Brunette, S. R.; Lipton, M. A. J. Org. Chem. 2000, 65, 5114-5119. Cramer, C. J.; Kormos, B. L.; Seierstad, M.; Sherer, E. C; Winget, P. Org. Lett. 2001, 3, 1881-1884. Maier, M. E.; Langenbacher, D. Synlett 1994, 713-716. Toshima, K.; Ohta, K.; Ohtake, T.; Tatsuta, K. Tetrahedron Lett. 1991, 32, 391-394. Toshima, K.; Ohta, K.; Ohtake, T.; Tatsuta, K. J. Chem. Soc, Chem. Commun. 1991, 694695. Myers, A. G.; Finney, N. S. J. Am. Chem. Soc. 1992,114, 10986-10987. Myers, A. G.; Dragovich, P. S. J. Am. Chem. Soc. 1993,115, 7021-7022. Feng, L.; Kumar, D.; Birney, D. M.; Kerwin, S. M. Org. Lett. 2004, 6, 2059-2062. Tuesuwan, B.; Kerwin, S. M. Biochemistry 2006, 45, 7265-7276. Ezcurra, J. E.; Pham, C; Moore, H. W. J. Org. Chem. 1992, 57,4787^789. Krause, N.; Hohmann, M. Synlett 1996, 89-91. Andemichael, Y. W.; Huang, Y.; Wang, K. K. J. Org. Chem. 1993, 58, 1651-1652. Datta, S.; Liu, R.-S. Tetrahedron Lett. 2005, 46, 7985-7998. Zhao, J.; Hughes, C. O.; Toste, F. D. J. Am. Chem. Soc. 2006, 128, l^fy-HT,!. Fujiwara, K.; Kurisaki, A.; Hirama, M. Tetrahedron Lett. 1990, 30,4329^1332. Myers, A. G.; Parrish, C. A. Bioconjugate Chem. 1996, 7, 322-331. [R] Kerwin, S. M. In Radical and Radical Ion Reactivity in Nucleic Acid Chemistry Greenberg, M., ed.; Wiley, New York, 2009, pp. 389^119. We thank Professor Sean Michael Kerwin for helpful discussions. Nicolaou, K. C; Maligres, P.; Shin, J.; de Leon, E.; Rideou, D. J. Am. Chem. Soc. 1990, 112, 7825-7826.

386

4.14

Name Reactions for Carbocyclic Ring Formations

Robinson annulation

Noha S. Maklad 4.15.1 Description

CXr X

—

CU»

The Robinson annulation was introduced in 1935 by Sir Robert Robinson and William Sage Rapson targeting the synthesis of building blocks of sterols. The condensation is an unprecedented reaction of alkali metal derivative of cyclohexanones and α,β-unsaturated methyl ketones that produces cycloketones and polycycloketones as precursors for sterols synthesis. 4.14.2 Historical Perpective Robert Robinson was a 1947 Nobel Laureate and a recipient of the order of merit; the tile is the most prestigious honor bestowed on a civilian in the United Kingdom.2 He was fascinated by developing new methods of steroid synthesis. Steroids are a class of compounds with important and diverse biological activities. In the realm of his fascination with this class of compounds and his diverse interests Robinson and co-workers in the 1930s began a series of 52 publications that have been published over 2 decades under the title "Experiments on the Synthesis of Substances Related to Sterols."1-10 In 1935 Robinson demonstrated a unique and unprecedented condensation of sodiocyclohexanone and its analogues with α,β-unsaturated methyl ketones. The finding not only has proven an important method for the synthesis of sterols; but, since its discovery, has also been extrapolated to the synthesis of complicated, diverse and important compounds. 4.14.3 Mechanism The mechanism of the Robinson annulation is explained in three distinct steps. Initially a vinyl ketone undergoes a Michael addition to a cyclic ketone or ß-keto ester to give the "3'-oxybutyl" adduct 1, which in turn is rearranged to give the 1,5-diketo adduct 2. u This step is then followed by

Chapter 4 Six-Membered Carbocycles

387

intramolecular aldol reaction to give the tertiary alcohol 3, and finally a dehydration step proceeds to give the octalone product 4. R

1. Micheal addition

base

H "3'-oxybutyl" Micheal adduct (1 )

-H

2. Intramolecular aldol

3. Dehyrdration

+H -H

1,5-diketone adduct (2)

Q^V

+H

OH

:B

H,0

03

k^-kAo

3

Under basic conditions and shorter reaction time, the ketol 3 and the enone 4 are detected in reaction mixture and can be separated. A higher yield for the enone can be obtained by separation of the Michael adduct 2 or the ketol 3 and either of these can then resubjected to less stringent conditions to form the enone 4 in higher yields.12'13 Regiocontrol for the Robinson annulation is an important factor that can influence a synthetic route because there are two α-carbons to the keto group to be considered. Consequently, techniques for regiocontrol have been developed. Under either the basic or acidic standard annulation conditions deprotonation occurs under thermodynamic control at the higher substituted carbon and hence forms an angular substitution at the fused side of the endproduct. An exception to this is steric hindrance where alkylation occurs at the least substituted α-carbon, as shown in the synthesis of 9.14

388

Name Reactions for Carbocyclic Ring Formations

Θ

o

v

ir

ether

υ

Methyl vinylketone (MVK)

LiNH2, ether reflux, 67%

The regiocontrol and stereocontrol aspects of the mechanism of this reaction will be explained under the next section. 4.14.4 Standard Method, Variations, and Improvements The Robinson annulation is the reaction of alkali metal derivatives of cyclohexanones with α-,β-unsaturated methyl ketones to produce cycloketones and polycycloketones. The standard method for Robinson annulation is exemplified in the mechanism shown above. For the synthesis of the 1,5-diketone side chain, the enolate nucleophile reacts with a Michael acceptor; this Michael acceptor is usually a substituted vinyl ketone or the parent methyl vinyl ketone (MVK), although the latter gives low yield due to its propensity to polymerize under the standard reaction conditions. To overcome the drawbacks for using MVK, Robinson, McQuillin and Du Feu introduced the Robinson-Mannich variation of the annulation reaction. ' This modification uses a quaternized Mannich base formed from the vinyl entity; the Mannich base is made in situ and acts as a methyl vinyl ketone precursor after it is converted to its methiodides. The formed methiodides of the Mannich adduct 4-(trimethylamino-2-butanone) is condensed with sodioderivatives of ketones or with the parent ketone in the presence of sodium ethoxide.

Chapter 4 Six-Membered Carbocycles

389 .OMe

NaNH2

benzene reflux, 71%

Ov

12

The generation of the enolate nucleophile can be attempted in different ways. The standard method introduced by Robinson is directed toward a thermodynamically controlled formation of the enolate where the deprotonation occurs at the higher substituted α-carbon to the ketone, thus creating a substitution at the ring juncture. The corresponding alkoxide forms by heating the starting ketone or ß-keto ester using sodium or lithium amide in an aprotic solvent such as ether or benzene. Other base/solvent combinations can be used such as lithium diisopropylamide (LDA) in THF at 20 °C.16 The enolate formation can also be achieved by subjecting the ketone to an alkoxide base in a protic solvent such as sodium methoxide in methanol or by a metal hydroxide base such as potassium hydroxide in methanol or ethanol.11·17 The Robinson annulation can also be conducted under acidic conditions. The first example reported was by Ellis and Heathcock in 1971. Acids such as sulfuric acid and /»-toluenesulfonic acid are used, although Robinson annulations under acidic conditions are not abundant in the literature.18 In the past 70 years different variations have immerged for the Robinson annulation reaction to rectify its weaknesses such as polymerization tendencies for the parent vinyl ketone under standard reaction conditions, multiple alkylation products, regiocontrol, and stereocontrol. Stork-Jung vinylsilanes variant. 9 In 1974 Stork and Jung introduced vinylsilanes as a carbonyl precursor for the Robinson annulation to be used as the Michael acceptor; the Stork-Jung vinylsilane 14 is shown below. The variation affects the alkylation step under mild conditions, and the release of the di-keto progenitor of cyclohexanones is straightforward. An example is the reaction of the lithium enolate 13 with the vinylsilane 14 in tetrahydrofuran at room temperature to give the silylated intermediate 15 in 91% yield. The silyl group is converted to ketone in the presence of w-chloroperbenzoic acid, and the reaction is conducted at 0 °C for a few minutes and then warmed to room temperature to give 16, which then proceeds to give the octalone 17 using potassium hydroxide in ethanol.

390

Name Reactions for Carbocyclic Ring Formations

„SiMei v

14(1 equiv) THF.r.t.,91%

OLi

SiMe,

O 15

13 m-chloroperbenzoic acid / \ / ^ \ ether, 0 °C to r.t.90% ^ " ^ O 16

3 M KOH /^°

EtOH 17

Stork-Enamine ketone variant 17,20-22 The Stork variation was pioneered by Stork and co-workers in 1963. It entails the reaction of pyrrohdine or morpholine enamine derived from unsymmetrical cyclohexanones with methyl vinyl ketones. The alkylation is directed to the less substituted carbon opposite to the alkylation regioisomer formed by the standard Robinson annulation conditions. Cyclization to the corresponding octalone then occurs. The morpholine enamine is less reactive than the pyrrohdine and hence pyrrohdine enamine has been mostly used for this approach. An example of such annulation is shown in the synthesis of 8methyl-2-oxo-A''9octalone (19). The pyrrohdine enamine of 2-methylcyclohexanone is refluxed in benzene with MVK for 24 h followed by the addition of an acetate buffer and reflux for 4 h, and after the reaction is worked up purification gives 19 in 45% yield. 1. benzene, reflux

» 2. acetate buffer, 45% 18

MVK

a-Silylated vinyl ketones23 The use of a-silylated vinyl ketone is another approach to overcome drawbacks of the standard Robinson annulation conditions such as polymerization of the vinyl ketöne. The a-silylated vinyl ketones are stable and can undergo Michael addition in standard aprotic conditions (conditions that induces polymerization for vinyl ketones), as well as protic conditions. Synthesis of the octalone 21 can be used as an example of this variation. The silylated ketone 20 reacts with lithium enolate 13 (generated by methyllithium from its corresponding enol silyl ether in THF) in /-butyl

391

Chapter 4 Six-Membered Carbocycles

alcohol; the reaction mixture is worked up and the crude is refluxed in 10% aqueous sodium hydroxide to give 21 in ~ 60% yield. SiMe3

1. f-butyl alcohol 2. 10% aq. NaOH, - 6 0 %

The alkylation can also occur under aprotic conditions such as in the formation of the octalone 23. The lithium enolate 22 is added to the ketone 20 in tetrahydrofuran at -78 °C, and then the mixture is allowed to reach room temperature. The alkylation process is followed by subjecting the silylated intermediate to 5% sodium methoxide-methanol to give 1-methylA1,9-octalone (23) in 80% overall yield. SiMe3 X

22

20

°

1. THF, - 78 °C-r.t. 2. 5% NaOMe/MEOH, 80% O' 23

Silyl-enol ether24~26 In 1975 Mukayaima's group used Lewis acid for the alkylation of silyl enol ethers with vinyl ketones, although the use of these conditions were only reported once afterward (in 1980) by a Japanese group as an alternative for the Robinson annulation. It was not until 1985 when Huffman, Satish and coworkers introduced a regioselective Lewis acid-catalyzed silyl enol ether variation to the Robinson annulation. The reaction depends on alkylation of silyl enol ethers in the presence of a T1CI4 or Ti(0/-Pr)4 catalyst or a combination of both, the latter showing the best results. Huffman and coworkers conducted the alkylation of the enol ethers with various Michael acceptors such as MVK, ethyl vinyl ketone (EVK), or their ketals to avoid polymerization, especially in the MVK case. The optimal alkylation temperatures are in the range of-80 °C to -90 °C. The formed 1,5-diketone can then be cyclized to the final Robinson enone using a base such as potassium hydroxide in ethanol . One of the importances of this approach is the ability to start with the preformed thermodynamic or kinetic enolate of the silyl enol ether and hence control the reaction regioselectively.27 An example of this is the formation of the 1,5-diketone 26 in 81% yield which is in turn cyclized to the eis- and irans-analogues 27a and b in 3:1 ratio.

392

Name Reactions for Carbocyclic Ring Formations

Although the yields of these products are not disclosed in their paper, it provides an interesting regioselective approach for the annulation reaction. QTMS

/~~\ P < ^ 1. TiCI4, Ti(0/-Pr)4 (1:1), DCM, -78 °C

ΊΙ 24

2. 10%HCI/THF(1:1), 81% 25

5% KOH/EtOH reflux

1

Sato and co-workers in 1991 showed the utilization of organotin triflate as the Lewis acid catalyst for the Michael addition step. Synthesis of octalone 30 is a good example in which silyl enol ether of cyclohexanone and MVK (1.3:1 ratio) reacts in DCM in the presence of 0.05 equivalent of Bu2Sn(OTf)2 at -78 °C. After alkylation was complete, sodium methoxide in methanol was added, and the mixture was stirred at room temperature to give 30 in an excellent 89% yield.28 OTMS

29

O

Bu2Sn(OTf)2 (0.05 e.q.)

MeONa

DCM

MeOH, r.t., 89%

MVK

30

Although there are different contributions in the field and the evolution of various Lewis acids used, to this day many chemists refer to the conditions of the reaction of silyl-enol ether with vinyl ketones in the presence of Lewis acid as "Mukayama-like" conditions. Aza-Robinson annulation29-31 There are few examples of this variation in the literature. The variation relies on the alkylation of thiolactams (in replacement of cyclohexanones) by the Michael addition of diazomethyl vinyl ketone (in replacement of methyl vinyl ketones) followed by ring closure using rhodium(II) acetate mediated diazomethane insertion. The diazomethyl entity can also be added after the Michael addition step.29'30 The reaction affords six-membered rings with

Chapter 4 Six-Membered Carbocycles

393

nitrogen at the ring juncture. Danishefsky and co-workers have shown a good example of such variation in the synthesis of compound 34a and 34b. The synthetic route starts with the alkylation with 32a to give the intermediate 33a in excellent 95% yield, followed by ring formation using rhodium(II) acetate and then raney nickel. On the other hand, the alkylation of thiolactam rings of X = H or n > 1 with diazomethyl vinyl ketone shows lower yields. An example is the reaction of the thiolactam 32 (X = H, n = 2) with the Michael acceptor 31a, which shows a low alkylation yield of 28%, by using methyl aery late 31b as the alkylating agent followed by the introduction of the diazomethyl entity, which gives 33b—the Michael adduci was hydrolyzed with NaOH followed by mixed anhydride formation and diazomethane addition—in 70% yield followed by ring formation to give 34b in 73%) yield. This method, although it involves more steps, is more reliable in producing the end product γ-pyridones in good yields.

Method A or B

31a X = CHN 2 32a X = C0 2 f-Bu, n = 1 (method A) 31b X = 0 M e 32b X = H, n = 2 (Method B) 33a X = C0 2 i-Bu,n = 1,95% 33b X = H, n =2, 70% 1.[Rh(OAc) 2 ] 2 benzene, reflux (» *2. W-2 Ra-Ni acetone 34a X = C0 2 f-Bu, n = 1,68% 34b X = H, n =2, 73%

Method A: NaOH (cat.), THF Method B: (i) NaOH (cat.), THF (ii) 1 N NaOH, MeOH (iii) CIC0 2 Et, CH 2 CI 2 (iv) CH 2 N 2 , Et 2 0

Gurana; Scarpi; et al. in 2000 introduced a modification to this variant which steers away from the use of the diazomethane addition step as shown in the synthesis of 38. Thiolactam 35 is alkylated with ethyl vinyl ketone in the presence of potassium carbonate and 18-crown-6 in tetrahydrofuran (ethyl vinyl ketone is introduced in excess by slow addition over a 2 h period to prevent ^-alkylation) to give the JV-alkylated ketone 36 in 97% yield. A thioiminium ion was formed with Me2SC>4 followed by cyclization with DBU under reflux to give 38 in a good 67% yield.31

Name Reactions for Carbocyclic Ring Formations

394

♦SAJ o

EVK

K2C03, 18-C-6 THF, 0-25 °C, 97%

35

DBU

Me2S04 toluene, reflux, 15 min.

MeS

refux, 67% o' 38

37

The Hajos-Wiechert reaction32,33 Developed in the early 1970s, this reaction, also called the Hajos-Parrish reaction or Hajos-Parrish-Ender-Sauer-Wiechert reaction, is one of the earliest processes for the stereoselective synthesis of Wieland-Miescher ketone, an important building block for steroids and terpenoid synthesis.34 This reaction is a proline mediated asymmetric variation to the Robinson annulation. Hajos and Parrish of Hoffmann-La Roche Inc. in 1971 and 1974 published an asymmetric aldol cyclization of triketones such as that of structure 39, which affords optically active annulation products in the presence of catalytic amounts of (5)-proline (Ζ,-proline).32 One of the early examples is the synthesis of 41 from the triketone 39 (a product of the Michael addition of MVK to the corresponding 2-methylcyclopentane-l,3dione), the reaction is performed in two steps: first by ring formation in the presence of 3 mol % of (5)-proline in DMF to afford the ketol 40 in 100% yield after crystallization with 93% ee and then by reaction with toluenesulfonic acid to give the dehydrated adduct 41. The formation of the Wieland-Miescher Ketone 44 follows the same synthetic route, starting from the tri-ketone 42 to give the end product in 75% optical purity and 99.8% of optical yield.

(S)-proline (3 mol%) ». DMF, r.t. 20 h, 100% O'

OH

6n6

40 (93% ee)

41

Chapter 4 Six-Membered Carbocycles

''

(S)-proline (3 mol%) DMF, r.t., 20 h, 52%

42

f^^

395

TsOH

^ ^

CT^^T OH 43

(S)-44

At the same time Eder, Sauer and Wiechert of Schering A.G. in 1971 published a one-pot reaction for the asymmetric synthesis of chiral bicyclics. The group affected this transformation from prochiral triketones in the presence of chrial amines or amino acids such as proline (similar to Hajos and Parrish). The (S)-amine or (5)-amino acid induces (.^-configuration bicyclics, while the (i?)-configuration outcomes varies. The best results for this annulation are shown in the synthesis of 41 and 44. The reaction is performed in the presence of (5)-proline and perchloric acid. The reaction mixture is heated under reflux to give the products in good 87% and 83% yields, respectively, and 84% and 71% ee, respectively.

(S)-Proline (47 mol%) 1 N HCI04, CH3CN 80 °C, 20 h, 87%

42

(S)-Proline (47 mol%) ^. 1 N HCIO4, CH3CN 80 °C, 25 h, 83%

Ö"

41 (84% ee

(S)-44 (71% ee)

Bui and Barbas in the year 2000 introduced a single-step enantioselective synthesis of the Wieland-Miescher ketone (44). The ketoenone 44 is formed by the reaction MVK, 2-methyl-l,3-hexadione, in the presence of (5)-proline in 49% and 76% ee. By screening the different catalysts, 46-^8 show synthesis of the (5)-(+)-44 in 60-75% ee.34 catalyst (30 mol%) DMSO, rt MVK

(S)-44 (60-75% ee)

396

Name Reactions for Carbocyclic Ring Formations catalysts HQ.

AcQ.

O, C02H

N H

N H

N H

46

47

48

Asymmetric aspects for the Robinson annulation In the Robinson annulation, cyclization to give the ketol intermediate can produce possibly five stereocenters. The dehydration process that follows minimizes the number of possible chiral centers to three or less.llb R

Rs

TT*° There are different approaches for stereocontrol for the Robinson annulation; the control can either arise from the inherent nature of the starting ketone and/or the vinyl ketones substituents in combination with the reaction conditions, or by the use of a chiral catalyst. In the first case, an example is the stereoselective aldol cyclization to give the ketol intermediate 50. ' c In this case the cyclization is kinetically controlled under protic basic conditions of sodium ethoxide and ethanol as it gives the cfs-fused adduct rather than the more stable /raws-fused ketol, which is not detected at any time during the reaction. NaOEt EtOH, 55% 49

OH 50

Sterics can influence the stereochemical outcome of the aldol cyclization, as in the case of the synthesis of the ketol 52 from the triketone 51 where R2 = OAc.35 In this case sterics stabilize the transition state that brings about the aldol cyclization to give the cz's-fused ketol 52, and a similar result occurs when R2 = CH3. Contrary results occurs when R = H or CN, and

Chapter 4 Six-Membered Carbocycles

397

under kinetically controlled conditions the outcome relies on the stability of the end-product and so gives the more stable trans-fased ketol.'1 OAc

OH

51

52

Solvents can influence the stereochemical outcome of the Robinson annulation. An interesting example is the one-step annulation using the sodium enolate of 49 to give the octalone 54 and 55. The reaction of the sodium enolate of the 2-methyl-cyclohexanone with trans-3-penten-2-one (53) in the presence of dioxane at room temperature for 100 h gives the cis4,10-dimethyl-A1,9octal-2-one (54) in 65% yield, while the reaction gives the /raws-isomer 55 in 72% yield in 3 h under same conditions.36 Method A or B

49

53

A = Dioxane, rt, 100 h, 65% B = DMSO, rt, 3 h , 72%

R% Λ»

54, R2 — R3 — CH3, R3' — H 55, R2 = R3 = CH3, R3 = H

A more efficient approach to control the stereochemical outcome for the Robinson annulation can be through the use of chiral catalysts such as in the case of the enantioselective Hajos-Wiechert variation introduced earlier. There are other chiral agents other than the popular (5)-proline-mediated annulation reaction that are used for these transformations—for example the use of (5)-2-(pyrolidinylmethyl)pyrrolidine in the presence of Bronsted acid such as trifluoroacetic (TFA). 7 This new catalyst for the Robinson annulation was reported in 2007 by Endo et. al., where the Bronsted acid, contrary to Hajos-Wiechert reaction, gives the (i?)-isomer of the WielandMiescher ketone 44 in a moderate yield of 47% and 75% ee.

OJ* 56

DMSO, TFA r.t., 80 h, 47%

(R)-44 (75% ee)

398

Name Reactions for Carbocyclic Ring Formations

Amines such as (S)- 1-phenylethylamine and (i?)-l-phenylethylamine can be used as chrial auxiliaries for the Robinson annulation. The secondary enamine of the ketone 57 with (£)- 1-phenylethy lamine reacts with MVK in tetrahydrofiiran for 30 h. This is then followed by the addition of 20% of acetic acid for 30 min. The intermediate formed is then cyclized with sodium methoxide in methanol to form (R)-59 in 50% overall yield and 92% ee.

(S)-1 -phenylethylamine toluene, reflux, 2 h, 98%

1.THF, 20 °C, 30 h 2. AcOH, 20 °C, 0.5 h

Ph

Me

HN

H +

MVK

NaOMe, MeOH 55 °C, 48 h, 50 % O' (R)-59 (92% ee)

In 1997 Barbas, Danishefsky, Zohng, and co-workers reported an antibody-catalyzed enantioselective Robinson annulation. The antibody used (Ab38C2) catalyzes the cyclodehydration step of the Robinson process for the prochiral starting triketone 60 to give (5)-44 in > 95% ee and with 96% optical purity. The reaction is carried out at room temperature for 10 days to give the product in a 94% yield.39 Ab38C2 CH3CN, H20, r.t. 10 d, 94%

(S)-44 (> 95% ee)

In 2009 Miro et al. reported the use of phosphoric acids as a chiral catalyst for enantioselective transformation of the Robinson annulation.40 Chrial phosphoric acids 61 and 62 are used in sequence first for the Michael reaction step and are then followed by the cyclization step. Synthesis of the annulation adduct 64 is shown as an example in the group's report. The cyclized adduct is formed from the reaction of the ß-keto ester 63 in the presence of the phosphoric acid 61 at 40 °C for 24 h and is followed by

Chapter 4 Six-Membered Carbocycles

399

refluxing in toluene for 48 h in the presence of the second phosphoric acid 62 to give the product in 64% yield and 96% ee.

62

C02Me 63

61 (2-10 mol%) 62 (10 mol%) m-xylene 40 °C, 24 h

toluene, reflux 48h, 64% (two steps)

C02Me 64

Use of directing group Hydroxymethylene group is used as a directing group for the annulation reaction; the group is added to the α-carbon of the starting ketone using ethylformate. The formation of the hydroxymethylene group directs alkylation to the less substituted position.11'41 A good example can be see in Robert Woodward's synthesis of intermediate 68 in his total synthesis of cholesterol.42 The bicyclic ketone 65 reacts with ethylformate in the presence of sodium methoxide in benzene, to give the formylated intermediate in 94% yield. The crude is then reacted with EVK and with a catalytic amount of potassium hydroxide in i-butanol to give the alkylated adduct 67 in 54% yield. Without further purification the crude was cyclized and the formyl group was removed in one step by potassium hydroxide in a mixture of water and dioxane to give 67 in 88% yield. ethylformate 65

NaOMe/benzene _. υ 94%

EVK, cat. KOH *f-BuOH 54%

400

Name Reactions for Carbocyclic Ring Formations

KOH dioxane, H 2 0, 88%

4.14.5 Synthetic utility General utility Robinson annulation has played a pivotal role in the synthesis cycloketones and polycycloketones for decades, and since its discovery it has been the keystone of many impressive syntheses. The decalin system is an abundant structure motif in terpenoid natural products, the ira/«-isomers more so than the cz's-isomers. Robinson annulation is a robust strategy for the synthesis of such molecules or their unsaturated congeners. Its importance lies especially in its ability to synthesize steroselectively the iraws-decalin skeleton. In the synthesis of compound 71 Robinson annulation assists in the formation of the compound's ABC ring motif.43 The ketone 69 is first alkylated with methyl formate to give the ß-keto carbonyl adduct 70 in 89% yield after purification. The product reacts with MVK and triethylamine at 0 °C, and the crude is subjected to concomitant cyclization and removal of the formyl group after workup using sodium methoxide in methanol which gives 71 as a single isomer in excellent 81 % yield. OMOM H

69

HC0 2 Me, NaH

H O

-THF, toluene, 0-25 °C MexV I ΓΜβ' 89% \ - ^ ' Ό 70

1.MVK, Et 3 N, 0 ° C 2. NaOMe/MeOH, 0 P C 8 1 % (two steps) 71

Chapter 4 Six-Membered Carbocycles

401

-O

72

y

{

?

73

X = C, R = CH 3 , base = NaOMe, 32% X = C, R = Ph, base = NaOMe, 28% X = N, R = COCH 3 , base = DBU, 37%

^XP ? H

cr^o 75

= Wang silyl (a) MeOH, H 2 0 (3:1) then base (b) TBAF, THF, r.t., overnight

Solid-phase techniques are also used for synthesis of compounds with trcms-decalin motif where the Robinson annulation is used for synthesis of some natural product inspired structures such as that of 75.44 The protocol uses an immobilized solid phase bound Nazarov reagent that reacts with the enamine of the starting ketone under basic conditions. After cyclization the product is released from the solid phase by using TBAF at room temperature overnight. For the products 75a-c only one stereoisomer was formed (de > 98%) with modest 22-38% yields. Robinson annulation is abundantly used in medicinal chemistry as a means for producing natural-product like structures such as Amgen's (AMG 067). The compound is a potent melanin-concentrating hormone receptor 1 (MCHrl) antagonist for the treatment of obesity.45 The benzylpiperidone (76) starting material is converted to the enamine 77 by gradual heating with pyrrolidine in toluene until reflux; the crude is then subjected to Michael addition of 3-penten-2-one (EVK) followed by cyclization to give a racemic

Name Reactions for Carbocyclic Ring Formations

402

mixture of syn- and a«tf-isomers (methyl related to the bridgehead substituent) and a mixture of α,β- and β,γ-enones 78a-d. The mixture is treated with di-p-toluoyl-L-tartaric acid (L-DTTA) in 80% ethanol/water which crystallizes the desired diastereomeric salt as an off-white solid. The process gives 76»L-DTTA of the (SS,8R) enantiomer, and so the optical purity revealed that the enantiomer is obtained as 97% ee and is produced in 28% yield from the starting benzylpiperidone. NBn

pyrrolidine toluene, reflux -H 2 0

76

o

/ \ Γ |

78a (±) 78b (±)

78c (±) 78d (±)

2. HOAc, NaOAc, H 2 0 3. aq. NaOH

77

NBn

1.EVK dioxane, 90 °C

L-DTTA

»- 76'L-DTTA EtOH, H20 28% from 76

FaQ

steps

Robinson annulation although not extensively has been used in synthetic routes toward complex carbohydrate structures such as in the synthesis of 82.46 The starting ketone 80 reacts with (trimethylsilyl)but-3-en2-one at -78 °C in the presence of lithium 2,2,6,6-tetramethylpiperidide (LTMP) base to give the alcohol 81. The a-methyl inverts to the axial position. The alcohol then produces the Robinson annulation adduct 82 in the presence of catalytic amount of methanolic potassium hydroxide in 58% yield. Me3Si\^^0 P

h

^ ^ è ^ 0

80

1.LTMP,Et2O,0°C,1h OMe 2 . \ ^

|

Ph^cbJn

N , -78 °C-r.t., 1 h

T O OH H ) ' OMe 81

Chapter 4 Six-Membered Carbocycles

KOH (0.3 equiv) MeOH, 80 °C, 6 h 58%

403

Ph^9^^.q OMe 82

The so-called homo-Robinson annulation, as pioneered and reported by Danishefsky in 2005, is an innovative Robinson annulation that can be used for the synthesis 7,5-fused rings such as bicyclo[5.3.0]decane ring (hydroazulene core). The annulation protocol uses the Robinson annulation techniques to form the starting ketone which undergoes ring expansion to give a 7,5-fused ring. In 2008 Danishefsky et al. reported a revised protocol to eliminate unwanted side reaction. On the route toward the synthesis of a natural product core, compound 88 was synthesized using this transformation. The Robinson annulation intermediate is synthesized through Mukayama-like conditions (BF3»Et20, acetic acid, and MVK) to give the Michael adduct 84. Cyclization was brought about by the use of sodium methoxide as a base. Ring expansion steps proceed with the cyclopropanation of a silyl enol ether (derived from the Robinson annulation adduct) with halocarbene that is followed by silver-promoted ring expansion to give the bromodienone in 59% yield (three steps from 85), which is reduced to give the hydroazulene adduct 88 in 41% yield.

(a) MVK, AcOH, BF3«Et20, -20 °C, 97%; (b) NaOMe, 98%; (c) (i) LDA, TMSCI, THF, -78 °C, (ii) CHBr3, KOf-Bu, peritane 0-23 °C; (d) AgN03, pyr, EtOH, 23 °C, 1.5 h, 59% (three steps from 3); (e) BF3«OEt2, Nal, CH3CN, 0 °C, 41%

404

Name Reactions for Carbocyclic Ring Formations

Applications in the total synthesis of natural products Robinson and Rapson first discovered this important transformation during there synthetic trials toward the synthesis of compounds with steroids structures such as sex hormones, e.g. oestrone and androgen, as well as their grand synthesis of cholesterol and many more syntheses. 1'48a_d In the 1950s cholesterol synthesis was considered to be one of the most important accomplishment that this annulation was used for during the 16 years since its initial discovery. Robinson reported the total synthesis of cholesterol almost at the same time as Robert Woodward of Harvard University. The synthetic route was published in its entirety in 1951, although parts of the synthetic routes were being worked on earlier, such as the pivotal step of the transformation of 1,6-dimethoxynaphthalene (84) to 5-methyl-ß-tetralone (86) as reported by Robinson and Cornforth in 1942. In the final RobinsonCornforth route, alkylation of 86 with methyl iodide in the presence of sodium methoxide gives 11 in 62% yield. The Robinson annulation then follows by refluxing the product with the Mannich adduct 10 (methyl vinyl ketone precursor) to give the intermediate 12 in 71% yield. The synthesis proceeds to a total of 38 steps as one of the first completed synthetic routes for cholesterol. LNaOH, Me2S04

*2. NaOEt/EtOH, 73%

cholesterol

Mel/NaOMe MeOH, 62%

Chapter 4 Six-Membered Carbocycles

405

Corey's enantiospecific synthesis of pseudopteroxazole shows a use of a modified Robinson annulation for the synthesis of the octalone ring 93,49 Silyl enol ether of the ketone 9 was synthesized under kinetic conditions of LDA and chlorotrimethylsilane. The intermediate is subjected to the Mukayama-Michael reaction conditions by reacting with l-benzyloxy-3methyl-but-3-en-2-one and SnCU, which gives the alkylation adduct 92 in 61% yield (as a mixture of diastereomers). The product is then cyclized through standard aldol cyclization conditions of 0.01 M of ethanolic solution of potassium hydroxide, which give a ketol intermediate. The hydroxy group of the tertiary alcohol is then eliminated to give the diastereomeric α,β-enone in 83% yield. The cyclized enone 93 then undergoes a different transformation to give the pseudopteroxazole (94).

c,d OBn 91 OTBDPS Me

OBn

OR 92 Me

O—λ

pseudopteroxazole (94) (a) LDA, TMS-CI, -78 °C, 100%. (b) 1-Benzyloxy-3-methylbut-3-en-2-one, SnCI4, CH2CI2, -78 °C, 61%. (c) KOH, EtOH, -10 °C, 83%. (d) SOCI2, pyridine, 83%.

4.14.6

Experimental

8-Methoxy-4a-methyl-4,4a,9,10-tetrahydrophenanthren-2(3H)-one(12)8 Diethylaminobutanone (15.05 g, prepared according Ref. 50) was swirled gently in a 1-L flask and cooled in ice during the addition of methyl iodide (15.0 g) in portions over 0.5 h. The swirling was regulated so as to obtain the crystalline methiodide as an even coating on the walls of the flask for 0.5 h and then under the tap for 45 min. A solution of the ketone (11) (20.0 g) in dry, thiophen-free benzene (100 cc) was added, air was expelled from the

406

Name Reactions for Carbocyclic Ring Formations

flask by dry nitrogen, and a solution of potassium (6.5 g) in dry ethanol (100 cc) added with ice cooling over 5 minutes. Swirling was continued until the methiodide had all dissolved (about 30 min) and was replaced by a precipitate of potassium iodide. After it had been kept in ice for another hour, the mixture was boiled gently for 25 minutes. An excess of 2 N-sulphuric acid was then added and the nitrogen stream stopped. After addition of enough water to dissolve the potassium sulphate the benzene layer was separated and the aqueous layer extracted twice with ether. The united extracts were washed with water, clarified with a little magnesium sulphate, and evaporated. The residue was distilled and 23.2 g were collected up to 180 °C/0.1 mm. The distillate was warmed until fluid, and ether added gradually until the total weight was 40 g. Crystallisation set in at once and was allowed to proceed at 0 °C overnight; the ketone (12) (17.0 g; m.p. 115-117 °C) was then collected and washed with chilled ether. The mother liquors after fractional distillation afforded an additional 1 g; the total yield was thus 71%. l,6-Dioxo-8a-Methyl-l,2,3,4,6,7,8,8a-Octahydronaphthalene(44)21

A mixture of 63.1 g (0.5 mol) 2-methyl-l,3-cyclohexanedione (45), 52.6 g (0.75 mol) methyl vinyl ketone, about 0.25 g (3 pellets) potassium hydroxide, and 250 mL absolute methanol is placed in a 500-mL round-bottomed flask fitted with a reflux condenser and a drying tube. The mixture was heated under reflux for 3 h, and the dione gradually went into solution. At the end of this period, methanol and the excess methyl vinyl ketone were removed by distillation under reduced pressure. The residual liquid was dissolved in 250 mL benzene, a Dean-Stark phase-separating head was attached, and 20 mL solvent was removed by distillation at atmospheric pressure to remove traces of water and methanol. The solution was cooled well below the boiling point, 3 mL of pyrrolidine is added and the mixture held at reflux for about 30 min, during which time about 9 mL of water collects in the trap. Refluxing was continued for an additional 15 min after the separation of water ceases. The water collected was removed, and then 50 mL of solvent was distilled. The reddish reaction mixture is cooled to room temperature and diluted with 150 mL ether. This solution was washed with 100 mL distilled water containing 15 mL 10% hydrochloric acid and 100 mL water. The aqueous extracts were extracted with 50 mL ether, and the combined organic layers were washed

Chapter 4 Six-Membered Carbocycles

407

with three 100-mL portions water, then with saturated salt solution and dried over magnesium sulfate. The solvents were then removed, and on distillation of the residue (82-85 g) at 0.5-1.0 mm the material, b.p. 117-145 °C, was collected and diluted with 5 mL of ether. The distillate was placed overnight in a refrigerator; the resulting crystals were then collected by rapid filtration and washed with about 25 mL cold ether. The first crop of diketone weighed 50-53 g and was colorless. The combined mother liquors were redistilled to obtain a further 4-6 g crystalline product. A yield of 56-58 g (63-65% based on dione) 1,6-dioxo-8a-methyl-1,2,3,4,6,7,8,8a-octahydronaphthalene (44), m.p. 47-50 °C, suitable for most other purposes, was obtained. 4.14.7 References 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18. 19. 20. 21. 22. 23. 24. 25. 26. 27. 28. 29. 30. 31.

Rapson, W. S.; Robinson, R. J. Chem. Soc. 1935, 1285-1288. [R] Laylin, K. Nobel Laureates in Chemistry; American Chemical Society & Chemical Heritage Foundation, Washington, D.C., 1993. Lewis, H. J.; Ramage, G. R.; Robinson, Robert./. Chem. Soc. 1935, 1412-1414. Robinson, R.; Schüttler, E. J. Chem. Soc. 1935, 1288-1291. Crowfoot, D. M.; Rapson, W. S.; Robinson, R. J. Chem. Soc. 1936, 757-759. Rapson, W. S. J. Chem. Soc. 1936, 1626-1628. Du Feu, E. C; McQuillin, F. J.; Robinson, R. J. Chem. Soc. 1937, 53-60. McQuillin, F. J.; Robinson, R. J. Chem. Soc. 1938, 1097-1099. Robinson, R.; Rydon, H. N. J. Chem. Soc. 1939, 1394-1405. Nunn, J. R.; Rapson, W. S.J. Chem. Soc. 1949, 825-831. [R] (a) Yung, M. E. Tetrahedron 1976, 32, 3-31, [R] (b) Gawley, R. E. Synthesis 1976, 777794. (a) Chen, E. Y. Synth. Commun. 1983, / / , 927-31. (b) Jansen, B. J. M.; Kreuger, J. A.; De Groot, A. Tetrahedron. 1989, 5, 1447-1452. (c) Marshall, J. A.; Fanta, W. I. J. Org. Chem. 1964,29, 2501-2505. Naussbaumer, C. Helv. Chim. Ada. 1990, 73, 1621-1636. Birch, A. J.; Robinson, R. J. Chem. Soc. 1944, 503-506. Cook, J. G.; Robinson, R. J. Chem. Soc. 1941, 391-393. Ziegler, F. E.; Hwang, K.-J. J. Org. Chem. 1983, 48, 3349-3351. Stork, G.; Brizzolarha, A.; Landesman, H.; Szmuszkovicz, J. J. Am. Chem. Soc. 1963, 207222. (a) Heathcock, C. H.; Ellis, J. E.; Tetrahedron Lett. 1971, 52, 4995-4996 (b) Paquette, L. A.; Belmont, D. T.; Hsu, Y. J. Org. Chem. 1985, 50,4667-4672. Stork, G.; Jung, M. E. J. Am. Chem. Soc. 1974, 96, 3682-3684. Telschow, J. E.; Reusch, W. J. Org. Chem. 1975, 40, 862-865. Ramachandran, S.; Newman, M. S. Org. Synth. 1973, Coll. Vol. 5, 486. Coates, R. M.; Shaw, J. E. J. Am. Chem. Soc. 1970, 92, 5657-5664. Stork, G.; Ganem, B. J. Am. Chem. Soc. 1973, 95, 6152-6153. Narasaka, K.; Soai, K.; Aikawa, Y.; Mukaiyama, T. Bull. Chem. Soc. Japan. 1976, 49, 779783. Yanami, T.; Miyashita, M.; Yoshikoshi. A. J. Org. Chem. 1980, 45, 607-612. Huffman, J. W.; Potnis, S. M.; Satish, A. V. J. Org. Chem. 1985, 50, 4266^1270. Stork, G.; Hudrlik, P.F. J. Am. Chem. Soc. 1968, 90,4462^1464. Sato, T.; Wakahara, Y.; Nozaki, H. Tetrahedron. 1991, 9773-9782. [R] Bergmann, E. D.; Ginsburg, D.; Pappo, R. Org. React. 1959, 10, 179-555. Fang, G. F.; Prato, M.; Kim, G.; Danishefsky, S. J. Tetrahedron Lett. 1989, 30, 3625-3628. Guarna, A.; Lombardi, E.; Machetti, F.; Occhiato, E. G.; Scarpi, D. J. Org. Chem. 2000, 65, 8093-8095.

408 32. 33. 34. 35. 36. 37. 38. 39. 40. 41. 42. 43. 44. 45. 46. 47. 48.

49. 50.

Name Reactions for Carbocyclic Ring Formations (a) Hajos, Z. G.; Parrish, D. R. German patent DE 71-2102623 (issued to HoffmanLaRoche). (b) Hajos, Z. G.; Parrish, D. R. J. Org. Chem. 1974, 10, 1615-1621. (a) Eder, U.; Sauer, G.; Wiechert, R. Angew. Chem.. Int. Ed. Engl. 1971, 10, 496-497; (b) Eder, U.; Sauer, G.; Wiechert, R. German patent DE 70-214757 (issued to Schering A.G.) Bui, T.; Barbas, C. F., Ill Tetrahedron Lett. 2000, 41, 6951-6954. Spencer, T. A.; Schmiegel, K. K.; Williamson, K. L. J. Am. Chem. Soc. 1963, 85, 37853793. Scanio, C. J. V.; Starrett, R. M. J. Am. Chem. Soc. 1971, 93, 1539-1540. Akahane. Y; Inage, N.; Nagamine, T.; Inomata, K.; Endo, Y. Heterocycles 2007, 74, 637648. (a) D'Angelo, J.; Desmaele, D.; Dumas, F.; Guingant, A. Tetrahedron: Asymmetry 1992, 3, 459-505. (b) Volpe, T.; Revial, G.; Pfau, M.; d'Angelo, J. Tetrahedron Lett. 1987, 28, 23672370. Zhong, G.; Hoffmann, T.; Lerner, R. A.; Danishefsky, S.; Barbas, C. F., III. J. Am. Chem. Soc. 1997, 119, 8131-8132. Akiyama. T.; Katoh, T.; Mori, K. Angew. Chem., Int. Ed. 2009, 48,4226-4228. Corey, E. J.; Nozoe, S. J. Am. Chem. Soc. 1963, 85, 3527-3528. Woodard, R. B.; Sondheimer, F.; Taub, D.; Heusler, k. J. Am. Chem. Soc. 1952, 74, 42234251. Ghosh, S.; Rivas, F.; Fischer, D.; Gonzalez, M. A.; Theodorakis, E. A. Org. Lett. 2004, 6, 941-944. Röttger, S.; Waldmann, R. Eur. J. Org. Chem. 2006, 2093-2099. Andersen, D.; Storz, T.; Liu, P.; Wang, W.; Li, L.; Fan, P.; Chen, X.; Allgeier, A.; Burgos, A.; Tedrow, J.; Baum, J.; Chen, Y.; Crockett, R.; Huang, L.; Syed, R.; Larsen, R. D.; Martinelli, M.; J. Org. Chem. 2007, 72, 9648-9655. (a) Borniert, R. V.; Jenkins, P. R. J. Chem. Soc, Chem. Commun. 1987, I, 6-7. (b) Borniert, R. V.; Howarth, J.; Jenkins, P. R.; Lawrence, N. J. J. Chem. Soc, Perkin. Trans. 1. 1991, 5, 1225-1229. (a) Yun, H.; Danishefsky, S. J. Tetrahedron. Lett. 2005, 46, 3879-3882. (b) Singh, M. P.; Janso, J. E.; Luckman, S. W.; Brady, S. F.; Clardy, J.; Greenstein, M.; Maiese, W. M. J. Antibiot. 2000, 53, 256-261. (a) Comforth, J. W.; Comforth, R. H.; Robinson, R. J. Chem. Soc. 1942, 689-691. (b) Comforth, J. W.; Robinson, Robert. Nature 1947, 160, 737-739. (c) Cardwell, H. M. E.; Comforth, J. W.; Duff, S. R.; Holtermann, H.; Robinson, R. Chem. Ind. 1951, 389-390. (d) Cardwell, H. M. E.; Comforth, J. W.; Duff, S. R.; Holtermann, H.; Robinson, R. J. Chem. Soc. 1953, 361-384. Davidson, J. P.; Corey, E. J. J. Amer. Chem. Soc. 2003,125, 3486-3489. Wilds, A. L.; Shurk, C. H. J. Am. Chem. Soc. 1943, 65, 471-475.

409

Chapter 4 Six-Membered Carbocycles

4.15 Scholl Reaction Richard J. Mullins and Michael T. Corbett 4.15.1 Description The Scholl reaction, formally representing a Friedel-Crafts arylation reaction, is the aryl-aryl coupling of two aromatic species 1 via dehydrogenation under Lewis acid and protic acid conditions. ίι ^ τ AICI 3, H

+

\ ^ ^ ί ^

4.15.2 Historical Perspective One of the more important and useful organic reactions, known as the Friedel-Crafts reaction, was discovered in 1877 by Charles Friedel and James Crafts.1 This class of reactions is generally thought to include all sets of electrophilic alkylation and acylation reactions on aromatic rings promoted by Lewis acids (traditionally AICI3 or FeCls) typically under anhydrous reaction conditions. Due to their synthetic utility, Friedel-Crafts reactions have been extensively studied and utilized across a broad and diverse area of chemical research. The aryl-aryl coupling reaction, currently known as the Scholl reaction, was first crudely observed by Friedel and Crafts in 1885 when it was determined that naphthalene in the presence of AICI3 formed an appreciable amount of β,β-dinapthyl at high temperatures.2 Similar observations were made by Homer in 1907;3 however, it was not until the early 1910s that Roland Scholl and co-workers began to investigate further and generalize this class of aryl-aryl coupling reactions under Friedel-Crafts conditions beginning with the syntheses of mesO-naphthodianthrone4 and 3hydroxy-1,2-benzfluorenone.5 Neither the synthetic scope nor mechanism was significantly investigated until 1935, when Baddeley and co-workers provided new insights into the Scholl reaction. Their work provided the first mechanistic interpretation, suggesting that the homocoupling reaction of naphthalene proceeds via an arenium cation intermediate.6 Based on experiments in

410

Name Reactions for Carbocyclic Ring Formations

which HC1 (a decomposition product of AICI3 in the presence of water) was excluded from the reaction, Baddeley determined that the presence of HO was essential for carrying out the Scholl reaction.7 It was also shown that the addition of NaCl results in the formation of NaAlCU, which does not promote the Scholl reaction. The Scholl reaction is traditionally run in the presence of a Lewis acid, such as FeCU or AICI3, under typical Friedel-Crafts conditions. Recently, however, various other oxidants have also been shown to effectively promote the reaction including CuCl2, Cu(OTf)2, M0CI5, SbCl5, etc., allowing for milder reaction conditions.8 4.15.3 Mechanism There are two plausible mechanistic pathways under debate for the Scholl reaction. The mechanistic uncertainty revolves around whether the reaction proceeds through cationic or radical cation intermediates. Both of these mechanisms are outlined below. The accepted mechanism, which proceeds through the arenium cation intermediate, occurs as follows.9'10 First, protonation of the aryl species 2 occurs to afford the electrophilic σ-complex 3. What follows is a two-step electrophilic aromatic substitution process whereby the electrophilic intermediate 3 is attacked by the adjacent aromatic ring to form a new carbon-carbon bond in intermediate 4. Deprotonation of 4 regenerates the aromatic species in intermediate 5. Finally, oxidation/aromatization of the product occurs with the formal expulsion of H2, resulting in the formation of 6.

Chapter 4 Six-Membered Carbocycles

411

The radical cation mechanistic pathway utilizing an oxidizing agent such as Q1CI2 is presumed to occur via a stepwise process characterized by isolable intermediates.9'11 In the mechanism, the aromatic species 7 undergoes a one-electron oxidation to provide the radical cation species 8. This radical cation 8 then undergoes an electrophilic carbon-carbon bond forming reaction with an adjacent aromatic ring to provide the ring-closed intermediate 9. Subsequent deprotonation of 9 regenerates the aromatic species in intermediate 10. Finally, the formal loss of an H-atom via the intermediate 10 results in aromatization and complete formation of the coupling adduct 11.

10

u

The arenium cation mechanistic pathway was first proposed in 1935 by Baddeley and was later reinforced by Balaban and Nenitzescu.6,12'13 Computational calculations performed by King and co-workers have produced several important conclusions.914 First, it was determined that the arenium cation mechanistic pathway was thermodynamically favored in studies under both vacuum and solvated conditions due to lower energy transition states than those found in the radical cation mechanistic pathway. Second, due to the increasingly exergonic nature of the reaction and the observed nonaccumulation of intermediates, C-C bond formation, in the case of hexaphenylbenzene, was found to occur slowest for the first bond and fastest for the last bond. The arenium cation mechanistic pathway is further supported by evidence that the Scholl reaction can proceed in acidic solutions that do not promote radical formation, such as anhydrous HF.15 The cationic mechanism has been shown to predominate in strongly protic conditions. ESR16 and EPR17 studies have concluded that the radical cations previously observed during the Scholl reaction are not part of the actual reaction, but

412

Name Reactions for Carbocyclic Ring Formations

rather are formed by the interaction of the polycyclic products with AICI3 in solution. The radical cation mechanistic pathway was first proposed in 1961 by Rooney and Pink18 and is also consistent with mechanisms proposed based on related studies performed on analogous classes of reactions.19'20 ESR studies have been performed to investigate the aromatic cation radicals present during the Scholl and have determined that radical species are present in reactions with AICI3.21'22 Calculations by Di Stefano and Negri also support the radical cation mechanistic pathway, which is consistent with observations made by Müllen and co-workers.11 The radical cation mechanistic pathway, which is stepwise, is supported by experimental evidence that intermediates can be isolated during the reaction, which is inconsistent with the arenium cation mechanism. 3 Further research by Kovacic into the role of oxidizing agents in the formation of radical cation species in the Scholl reaction has also provided some experimental evidence to support this pathway.8 The limited knowledge of the mechanism to date has caused a schism to form due to insufficient physical evidence to support either mechanistic pathway definitively. Thus the reader is directed to the aforementioned papers for a complete understanding of the mechanism. 4.15.4 Variations and Improvements While the original Scholl conditions called for both a Lewis and protic acid, research by Kovacic and Kyriakis into the role of oxidizing agents (that facilitate the formation of radical cations) in the Scholl reaction led to the observation that benzene (12) when reacted in the presence of a heterogeneous mixture of anhydrous aluminum chloride and copper chloride afforded poly(para-phenylene) (13).8'24'25 It is important that this reaction was conducted under mild conditions (25-35 °C) and was complete in only 2 h. As discoverers of one of the first Scholl reactions conducted under mild conditions, Kovacic and Kyriakis have greatly increased the synthetic utility of this reaction.

0 12

AICI3, CuCI2 25-35 °C, 2 h 13

4.15.5 Synthetic Utility Although the Scholl reaction has been known for almost a century, due to the harsh reaction conditions, its synthetic utility had, until recently, not been

Chapter 4 Six-Membered Carbocycles

413

extensively explored. With the discovery by Kovacic and co-workers, its synthetic scope has been significantly broadened through the adoption of efficient and mild reaction conditions.25 For an extensive survey of the Scholl reaction before 1970, the reader is led to the review by Balaban and Nenitzescu.10 One of the earliest examples of the Scholl reaction was performed during the ring-closing synthesis of 3-hydroxy-l,2-benzfluorenone (15).5 Using 4-hydroxy-l-benzoylnaphthalene (14) under Friedel-Crafts conditions, the desired product 15 was obtained in high yield along with only trace amounts of 16, suggesting important substituent effects in the reaction. Substituted 1,2-benzfluorenes have also been accessed using this approach.26

Musgrave and Buchan developed a procedure for the preparation of triphenylene-1,4-quinones from 2,3-diaryl-l,4-benzoquinones using an acid97

catalyzed intramolecular Scholl reaction. Using the 2,3-diaryl-l,4benzoquinone 17, the AlCh-mediated cyclization occurred to afford a quinol intermediate that was then oxidized in the presence of FeCb to afford the triphenylenequinone 18 in moderate yield under mild reaction conditions. Inclusion of 2,3-dichloro-5,6-dicyano-l,4-benzoquinone (DDQ) as an oxidant has also been shown to increase the yield of the reaction up to 50%.

0

1. AICI 3, CS 2 , r.t., 3 days 2. FeCI 3 , CHCI3

32%

M e 0

MeO

OMe OMe

OMe OMe

The intermolecular version of the Scholl reaction is much less prevalent in the literature due to the difficulty in controlling the formation of the desired products. Bushby and co-workers have used an intermolecular version of the Scholl reaction in efforts toward the synthesis of chirally discotic liquid crystals featuring the triphenylene nucleus.28 The fluorobenzene derivative 20 was coupled with the symmetric biphenyl 19 to

414

Name Reactions for Carbocyclic Ring Formations

afford the desired product 21, the structure of which was determined by NOE analysis.

FeCI3, CH 2 CI 2 , 2 h » ^OR 69% 20

^

=

"(C^O-CHS

OR

OR 19

21

In the early 1990s, an increased interest in molecular electronics has led to the desire to obtain functionally and geometrically interesting planar organic species via facile synthetic routes.29' ° As such, the Scholl reaction has become increasingly useful due to its ability to effect intramolecular aryl-aryl coupling reactions in a controlled manner. To meet the needs in this area, milder reaction conditions have been developed, making the Scholl reaction more applicable to the synthesis of compounds with sensitive functionality. OMe

OMe

FeCI 3 CH2CI2/CH3NO2 25 °C, 45 min. MeO

OMe

36%

MeO

OMe

The Scholl reaction has been extensively used to obtain a wide range of functionalized and fully cyclized hexa-pen'-hexabenzocoronenes (HBCs). These compounds are useful because of their potential application as organic semiconductors for use in a wide range of electronic and optoelectronic devices due to their robustness and ability to effectively π-stack. An example is the structurally interesting C3 symmetric meta-trimethoxy substituted HBC with alternating methoxy and tert-butyl substituents synthesized by Müllen and co-workers.31 The Scholl reaction precursor 22 was synthesized via a

Chapter 4 Six-Membered Carbocycles

415

Co2(CO)8-catalyzed cyclotrimerization. The subsequent FeCl3-mediated planarization of 22 under mild reaction conditions afforded the HBC 23 in moderate yield.

The arrangement of substituents in the hexaphenylbenzene precursor for most HBCs has been known to play a significant role in the outcome of the Scholl reaction. Therefore, acquiring some HBCs is not as synthetically straightforward as it may be perceived. Rearrangements during the Scholl reaction were first observed by Müllen and co-workers during the proposed synthesis of dimethoxy-substituted HBCs. Subjection of the paradimethoxy HBC 24 to Scholl conditions provided a mixture of the only observed HBC product 25 (20%) and bis-spirocyclic dienone 26 (70%) while none of the predicted product 27 was observed. The observed rearrange-

416

Name Reactions for Carbocyclic Ring Formations

ments are consistent with both arenium cationic and radical cation mechanisms. The implications of substituent arrangements on the course of the Scholl reaction along with synthetic strategies to bypass these roadblocks have been extensively studied by King and co-workers.33'34 An example of this is work by Rathore and co-workers that sought to avoid the spirocycle formation first observed by Müllen by employing new precursor geometries.35 Using the alkoxy-precursor 28, the hexaalkoxy HBC 29 can be obtained in nearly quantitative yields with no observed spirocycle formation. Long alkyl groups are necessary for the reaction to proceed, however, since no desired product is observed when R = CH3.

Nontraditional HBC architectures have also gained synthetic interest recently. Contorted HBCs were expeditiously synthesized in three facile steps by Nuckolls and co-workers using a FeCl3-mediated Scholl reaction.36 The Scholl reaction precursor 30 was obtained via a two-step synthesis from a soluble pentacene quinone derivative which could then undergo an intramolecular cyclization to afford the contorted HBC 31 in high yield.

Chapter 4 Six-Membered Carbocycles

417

Although some substrates do not undergo complete cyclization, the Scholl reaction has been shown to be broadly applicable as an effective route towards these types of HBCs. Research into the preparation of heterocyclic HBCs has also come to the foreground in the literature. The development of pyrimidyl-pewtophenylbenzene systems was sought by Gourdon and co-workers to access novel optoelectronic materials from hetero-oligophenylenes.37 Substitution on the pyrimidyl moiety greatly altered the degree of cyclization observed in the products. When precursor 32 was treated under Scholl conditions, the fully-cyclized diaza-hexa-pen'-benzocoronene 33 was obtained in moderate yield. It is interesting that without the i-butyl substituent at the 2 position of the pyrimidine ring, incomplete cycloaddition was observed, only occurring ortho to the nitrogens in the pyrimidine moiety. This partial cyclization38 has been exploited to the advantage of Moore and co-workers for the preparation of semifused HBCs, with interesting fluorophoric properties.39 The isolation of these semi-fused HBCs has been cited as evidence for the stepwise radical cation mechanism proposed by Müllen.23

R

R FeCI3/CH3N02

*-

CH2CI2, 60% R

R = f-Bu

R

In addition to the ongoing research into the preparation of fiinctionalized hexa-pen'-benzocoronenes, there has been significant interest in the preparation of extended aromatic networks. Vingiello and co-workers used the Scholl reaction to obtain polycyclic aromatic compounds from 1arylbenz[a]anthracenes.40 1-Phenylbenz[a]anthracene (34) when reacted under Scholl conditions in the presence of stannic chloride afforded dibenzo[a,/]pyrene (35) in moderate yield after just 5 min.

418

Name Reactions for Carbocyclic Ring Formations

34

35

Müllen and co-workers have developed a procedure for converting stilbenoids to extended aromatic systems using a combination of [2 + 2]cycloadditions followed by a Scholl cyclodehydrogenation.41 Subsequent intermolecular and intramolecular cycloaddition reactions provide the polybenzenoid arene 36, which exists as a mixture of conformations 36a and 36b in equilibrium at room temperature. As result of this conformational equilibrium, the AlC^-mediated cyclodehydrogenation afforded the isomerie mixture of 37 and 38.

Research by Müllen and co-workers has continued to expand into the field of large polycyclic aromatic networks. Using similar approaches, molecular propellers have been synthesized using simple cyclodehydrogenation reactions of dendrimeric HBC-precursor materials.42 Further work has

Chapter 4 Six-Membered Carbocycles

419

led to the formation of up to 12-nm-long two-dimensional graphene nanoribbons from a nonplanar precursor.4 The sterically hindered polyphenylene 39 was obtained through a Suzuki-Miyaura coupling polymerization. The FeC^-mediated oxidative cyclodehydrogenation of 39 afforded the aromatic ribbon 40 in good yield.

40

Use of the Scholl reaction for polymerization of substituted aromatic rings has precedence in the literature as well due to the facile and often predictable aryl-aryl coupling using these conditions. Geerts and co-workers used the Scholl reaction to access poly(p(ara-phenylene) (13), which is used in blue light-emitting diodes, and other soluble poly(para-phenylene)s such as 41. The use of M0CI5 as the oxidant afforded the desired polymers 13 and 41 in one-step with moderate molecular weights, low PDIs, and high para regioselectivity. For a more thorough review of the Scholl reaction's synthetic utility for the synthesis of poly(phenylene)s, the reader is directed to a review by Kovacic and Jones.8

Name Reactions for Carbocyclic Ring Formations

420

MoCI 5

^^Yj13

ρθβΗ17

MoCI

5 ,

C8H170

OC 8 Hi7

-^Yr ΟβΗ-^Ο

^

Percec and co-workers have also employed the Scholl reaction in a variety of polymerization reactions, especially for the synthesis of aromatic poly ethers.45 The 1-naphthol derivative 42 underwent the cation-radical polymerization under Scholl conditions to afford the polyether 43 in high conversion. As a major contributor to this area, Percec has used the Scholl reaction in a similar manner in various other polymerization studies of aromatic polyethers 46-55 The Scholl reaction also been employed in polymerizations of binapthyl,56-58 4-methyltriphenylamine,59 and 1,3-di-«butoxybenzene,60 -based systems.

4.15.6 Experimental OR

OR

FeCI, 20 min., 98% R = -(CH2)irCH3

Chapter 4 Six-Membered Carbocycles

421

10-Bromo-2,3,6,7,14,15,18,19-octakis(dodecyloxy)trinaphtho[l,2,3,4^A:l,,2,,3',4,-/»ir:l",2",3",4M
Friedel, C; Crafts, J. M. Compt. Rend. 1877, 84, 1450-1454. Friedel, C; Crafts, J. M. Compt. Rend. 1885,100, 692-698. Homer, A. J. Chem. Soc., Trans. 1907, 91, 1103-1114. Scholl. R.; Mansfeld, J. Ber. 1910, 43, 1734-1746. Scholl, R.; Seer, C. Ann. 1912, 394, 111-123. Baddeley, G.; Kenner, J. J. Chem. Soc. 1935, 303-309. Baddeley, G. J. Chem. Soc. 1950, 994-997. [R] Kovacic, P.; Jones, M. B. Chem. Rev. 1987, 87, 357-379. Rempala, P.; Kroulik, J.; King, B. T. J. Org. Chem. 2006, 71, 5067-5081. [R] Balaban, A. T.; Nenitzescu, C. D. In Friedel-Crafts and Related Reactions; G. A. Olah, Ed.; Interscience, New York, 1964, Ch. 23. Di Stefano, M.; Negri, F.; Carbone, P.; Müllen, K. Chem. Phys. 2005, 314, 85-99. Nenitzescu, C. D.; Balaban, A. T. Chem. Ber. 1958, 91, 2109-2116. Balaban, A. T.; Nenitzescu, C. D. Acad. Repub. Pop. Rom., FU. Cluj. Stud. Cercet. Chim. 1959, 7, 521-529. Rempala, P.; Kroulik, J.; King, B. l.J. Am. Chem. Soc. 2004,126, 15002-15003. Simons, J. H.; McArthur, R. E. J. Ind. Eng. Chem. 1947, 39, 364-367. Rang, H.; Kispert, L. D.; Sang, H. J. Chem. Soc. Perkin Trans. II1989, 1463-1469. Wang, T.; Wu, A.-A.; Gao, L.-G.; Wang, H.-Q. Chin. J. Chem. Phys. 2009, 22, 51-56. Rooney, J. J.; Pink, R. C. Proc. Chem. Soc. 1961, 142-143. Pummerer, R.; Luther, F. Ber. Dtsch. Chem. Ges. 1928, 61, 1102-1107. Rooney, J. J.; Pink, R. C. Trans. Faraday Soc. 1962, 58, 1632-1641. Lehnig, M.; Reiche, T.; Reiss, S. Tetrahedron Lett. 1992, 33, 4149^1152. Bakker, M. G.; Claridge, R. F. C; Kirk, C. M. J. Chem. Soc, Perkin Trans. II, 1986, 17351741. Kübel, C; Eckhardt, K.; Enkelmann, V.; Wegner, G.; Müllen, K. J. Mater. Chem. 2000, 10, 879-886. Kovacic, P.; Kyriakis, A. Tetrahedron Lett. 1962,467-469. Kovacic, P.; Kyriakis, A. J. Am. Chem. Soc. 1963, 85, 454-458. Gross, M. E.; Lankelma, H. P. J. Am. Chem. Soc. 1951, 73, 3439-3442. Buchan, R.; Musgrave, O. C. J. Chem. Soc, Perkins Trans. 11975, 568-572. Boden, N.; Bushby, R. J.; Cammidge, A. N.; Duckworth, S.; Headdock, G. J. Mater. Chem. 1997,7,601-605. [R] Berresheim, A. J.; Müller, M.; Müllen, K. Chem. Rev. 1999, 99, 1747-1785. [R] Watson, M. D.; Fechtenkötter, A.; Müllen, K. Chem. Rev. 2001,101, 1267-1300. Feng, X.; Pisula, W.; Takase, M.; Dou, X.; Enkelmann, V.; Wagner, M.; Ding, N.; Müllen, K. Chem. Mater. 2008, 20, 2872-2874.

422 32. 33. 34. 35. 36. 37. 38. 39. 40. 41. 42. 43. 44. 45. 46. 47. 48. 49. 50. 51. 52. 53. 54. 55. 56. 57. 58. 59. 60.

Name Reactions for Carbocyclic Ring Formations Dou, X.; Yang, X.; Bodwell, G. J.; Wagner, M.; Enkelmann, V.; Müllen, K. Org. Lett. 2007, 9, 2485-2488. King, B. T.; Kroulik, J.; Robertson, C. R.; Rempala, P.; Hilton, C. L.; Korinek, J. D.; Gortari, L. M. J. Org. Chem. 2007, 72, 2279-2288. Ormsby, J. L.; Black, T. D.; Hilton, C. L.; Bharat; King, B. T. Tetrahedron 2008, 64, 1137011378. Wadumethrige, S. H.; Rathore, R. Org. Lett. 2008,10, 5139-5142. Plunkett, K. N.; Godula, K.; Nuckolls, C; Tremblay, N.; Whalley, A. C; Xiao, S. Org. Lett. 2009,77,2225-2228. Nagarajan, S.; Barthes, C; Gourdon, A. Tetrahedron 2009, 65, 3767-3772. Iyer, V. S.; Wehmeier, M.; Brand, J. D.; Keegstra, M. A.; Müllen, K. Angew. Chem., Int. Ed. 1997, 36, 1604-1607. Lu, Y.; Moore, J. S. Tetrahedron Lett. 2009, 50, 4071^1077. Vingiello, F. A.; Yanez, J.; Campbell, J. A. J. Org. Chem. 1971, 36, 2053-2056. Müller, M.; Mauermann-Düll, H.; Wagner, M.; Enkelmann, V.; Müllen, K. Angew. Chem., Int. Ed. 1995,34,1583-1586. Simpson, C. D.; Mattersteig, G.; Martin, K.; Gherghel, L.; Bauer, R. E.; Räder, H. J.; Müllen, K.J. Am. Chem. Soc. 2004, 126, 3139-3147. Yang, X.; Dou, X.; Rouhanipour, A.; Zhi, L.; Räder, H. J.; Müllen, K. J. Am. Chem. Soc. 2008,730,4216^217. de Halleux, V. M.; Geerts, Y. H. React. Fund. Polym. 2000, 43, 145-151. Percec, V.; Wang, J. H.; Yu, L. Polym. Bull. 1992, 27, 503-510. Percec, V.; Nava, H. J. Polym. Sci., Part A: Polym. Chem. 1988,26, 783-805. Percec, V.; Wang, J. H.; Oishi, Y. J. Polym. Sci., Part A: Polym. Chem. 1991, 29, 949-964. Percec, V.; Wang, J. H. Polym. Bull. 1991, 25, 9-16. Percec, V.; Wang, J. H.; Oishi, Y.; Feiring, A. E. J. Polym. Sci., Part A: Polym. Chem. 1991, 29, 965-976. Percec, V.; Wang, J. H.; Okita, S. J. Polym. Sci., Part A: Polym. Chem. 1991, 29, 17891800. Percec, V.; Okita, S.; Wang, J. H. Macromolecules, 1992,25, 64-74. Percec, V.; Wang, J. H.; Okita, S. J. Polym. Sci., Part A: Polym. Chem. 1992, 30,429-438. Percec, V.; Wang, J. H.; Oishi, Y. J. Polym. Sci., Part A: Polym. Chem. 1992, 30,439^48. Percec, V.; Wang, J. H. J. Mater. Chem. 1991, 7, 1051-1056. Percec, V.; Wang, J. H.; Yu, L. Polym. Bull. 1992, 27, 503-510. Tanaka, M.; Nakashima, H.; Fujiwara, M.; Ando, H.; Souma, Y. J. Org. Chem. 1996, 61, 788-792. Abd-El-Aziz, A. S.; de Denus, C. R.; Todd, E. K.; Bernardin, S. A. Macromolecules 2000, 33, 5000-5005. Okada, T.; Ueda, M. React. Fund. Polym. 1996, 30, 157-163. Strzelec, K.; Fugino, N.; Ha, J.; Ogino, K.; Sato, H. Macromol. Chem. Phys. 2002, 203, 2488-2494. Okada, T.; Fujiwara, N.; Ogata, T.; Haba, O.; Ueda, M. J. Polym. Sci., Part A: Polym. Chem. 1997, 35, 2259-2266.

Name Reactions for CarbocycUc Ring Formations Edited by Jie Jack Li Copynght © 2010 John Wiley & Sons, Inc.

Chapter 5 Large-Ring Carbocycles

423

5.1 5.2 5.3 5.4

424 451 489 578

Büchner Reaction de Mayo Reaction Ring-closing Metathesis (RCM) Thorpe-Ziegler Reaction

Name Reactions for Carbocyclic Ring Formations

424

5.1

Büchner Reaction

Yong-Jin Wu 5.1.1 Description The Büchner reaction describes cyclopropanation of an aromatic double bond with the oc-ketocarbene derived from an oc-diazocarbonyl compound 1 to produce an unstable norcaradiene intermediate 2, which is in thermal equilibrium with the more stable cycloheptatriene tautomer 3. This tautomer undergoes thermally or photochemically induced electrocyclic ring opening to give other cycloheptatriene isomers 4-6. ' hv; or Δ; orMLn

,.c(o,R — . Q ^ R — Q ^ R ^ \

p

2

/^x

n

3

I 6

5

4

5.1.2 Historical Perspective Since Theodor Curtius reported the synthesis of ethyl diazoacetate in 1883,3 Büchner had investigated its reactions with carbonyl compounds, alkenes, alkynes, and aromatic compounds for more than 30 years. b His extensive contributions in this area resulted in two reactions named in his honor: the Buchner-Curtius-Schlotterbeck reaction (formation of ketones from aldehydes and aliphatic diazo compounds) and the Büchner reaction. The prototypical example of the latter involves the thermal or photochemical reaction of ethyl diazoacetate with benzene to give (via norcaradiene 7) a mixture of four isomerie cycloheptatrienes 8-11. Initially, Büchner believed that a single norcaradiene product 7 was generated from this reaction, but later, he realized that the hydrolysis of the product afforded a mixture of four isomerie carboxylix acids. The norcaradiene formulation persisted until 1956 when Doering reinvestigated this reaction.4

Chapter 5 Large-Ring Carbocycles

hv;orA; + N2=CHC02Et -

425

Z55^ | V-C02Et

r^^N. Γ h^C02Et = = 7

^jh-C02Et 11

+

8

Q-C02Et 10

+

(^jKC0 2 Et 9

The thermal or photochemical Büchner reactions produce complex mixtures of cycloheptatrienyl esters, and the daunting complexity of the product mixtures was reduced or even eliminated with the advent of transition-metal catalysts, at first copper-based, then in the early 1980s rhodium(II) catalysts, which were developed by the Belgium group led by Noels and Hubert.5 The rhodium(II)-catalyzed cyclopropanations of aromatics, especially intramolecular cyclopropanations, have enjoyed a certain popularity due to their high regioselectivity and stereoselectivity. Since the intramolecular Büchner reaction is much more widely used in organic synthesis than the intermolecular version, the former is the focus of this review. The Büchner reaction resulted from his pioneering contribution to the reactions of arenes with oc-diazoketones. Eduard Buchner (1860-1917) obtained his Ph.D. in Munich in 1888 under the supervision of Theodor Curtius (1857-1928). His graduate studies resulted in "A New Synthesis of Trimethylene Derivetives," in which he demonstrated the existence of a cyclopropanol ring. As a postdoctoral researcher, Büchner synthesized pyrazole for the first time in 1891. Since then, Büchner had taken over and further developed the chemistry of doazoalkanes from his mentor Theodor Curtius. Eduard Buchner made substantial contributions not only to organic chemistry but also to biochemistry. About half of his 120 scientific publications are dedicated to his research in biochemistry, and in fact, he is regarded as one of the fathers of modern biochemistry. In 1897, Eduard Buchner (together with his brother Hans Büchner) discovered quite by accident that fermentation could occur outside living cells, thus disproving a long held belief, asserted by Louis Pasteur in 1860, that fermentation is inextricably tied to living cells. His chance discovery, which opened the door to modern biochemistry, led him to the award of the Nobel Prize for chemistry in 1907.

Name Reactions for Carbocyclic Ring Formations

426

Buchner's life ended tragically. He was killed in Romania in 1917 while serving as a major in World War I. 5.1.3 Mechanism The transition-metal-catalyzed decomposition of a diazo carbonyl compound 12 generates a metal-carbene complex 13, which is electrophilic. This carbene intermediate undergoes [2 + 2] cycloaddition to give a fourmembered ring intermediate 16 that incorporates the metal. Reductive elimination of 16 leads to the cyclopropanation product 17. Alternatively, neucleophilic addition of the benzene aromatic double bond with the carbene complex 13 gives a polar species 15, which undergoes 1,3-bond formation to give 17. The additions of metal-carbene complexes to aromatic double bonds are stereospecific, suggesting that if an open-chain is involved, it must collapse to the product more rapidly than single-bond rotations to avoid any loss of stereoselectivity. Ri R2

MLn

Θ

LnM

® Ri

L n

13

Θ

® ML n R

o

R2 14

R2

12

M=^

MLn -R1

2^0

R*

15

16

-O

H

HR2 17

The catalytic cycle of the transition-metal-catalyzed Büchner reactions can be generally described as below:

Chapter 5 Large-Ring Carbocycles

427

MLn

R2

2

R

LnM

5.1.4

Ri N,

Transition Metal-Catalyzed Büchner Reactions

The problems endemic to the thermal and photochemical Büchner reactions were solved comprehensively in 1980 when rhodium(II) catalysts were introduced.5 The measurement of improvement using Rh(II) catalysts can be appreciated by comparing the thermal reaction of ethyl diazoacetate with anisole (35% yield, seven products) with its rhodium trifluoroacetatecatalyzed counterpart (83% yield, three products 19-21). The methoxy substituent clearly exerts a directive effect in favor of the 4-methoxy isomer 19, and all the products are kinetically controlled unconjugated esters. In general, the rhodium(II)-catalyzed decomposition of alkyl diazoacetates in the presence of a large excess of aromatic substrates at room temperature affords kinetically controlled cycloheptatrienyl esters in excellent yield. OMe

.OMe

Rh 2 (OCOCF 3 ) 4 83% N 2 =CHC0 2 Et

·

Et02C

0Me

20 (29%)

ÒOTB

21 (8%)

Double cyclopropanation of benzene occurs in the Rh(II)-catalyzed reaction of dimethyl diazomalonate 22.7 Heating a benzene solution of this diazo compound and rhodium(II) acetate (1 mol %) under reflux gives a mixture of [23 + 24] ( 19%), 25 (8% yield) and bis-cyclopropanation product 26 (58% yield). When the same reaction is carried out using rhodium(II) trifluoroacetate instead of rhodium(II) acetate as the catalyst, a vastly different product distribution is obtained: [23 + 24], 64%; 25, 32%; 26, 4%. The low yield of double cyclopropanation product 26 obtained with rhodium(II) trifluoroacetate is comparable to other carbenoid reactions with aromatic substrates, where double cyclopropanation is rare.

428

Name Reactions for Carbocyclic Ring Formations

0

C02Me

+

22 1

C02Me

Rh2(OAc)4

/Vc0 2 Me

'C02Me !4

c

C02Me

19%

N_/C0 2 Me H 23

■

C02Me cy< V_j/ C0 Me 2

25 (8%)

Me0 2 C-^^C0 2 Me

Me02C

C02Me

26 (58%)

The intramolecular Büchner reaction of aryl diazoketones has been carried out using both copper(I) and rhodium(II) catalysts. For example, 1diazo-4-phenylbutan-2-one 27a cyclizes in bromobenzene with copper(I) chloride catalysis, furnishing 3,4-dihydroazulen-l(2//)-one 30 in 50% yield after purification by chromatography over alumina.8 Trienone 30 is not the primary cyclization product, and the less conjugated isomerie trienone 29a is first produced, but contact with alumina causes isomerization to 30. The yield of this cyclization is further improved when rhodium(II) acetate is used as the catalyst instead of copper(I) chloride. Thus a catalytic amount of rhodium(II) acetate brings about the nearly quantitative conversion of 27a to 29a within minutes in hot dichloromethane. Compound 29a isomerizes to 30 on treatment with triethylamine, and rearranges to 2-tetralone 31a when exposed to silica gel or acid. The rhodium(II) trifluoroacetate-catalyzed cyclization of the disubstituted diazoketone 27b also proceeds smoothly, but the product is a equilibrium mixture of cycloheptatrienone 29b and norcaradiene-like tricyclic tautomer 28b, with the tricyclic form 28b the dominant partner at room temperature.9

Chapter 5 Large-Ring Carbocycles

429

i

Rh2(OAc)4 R

N2 27a/b

28a/b

29a/b

silica gel ,, or acid

a:R = H b: R = Me

Et3N 1 (R = H)

31a/b

The effect of ortho- and weto-substitution in the above-mentioned intramolecular Büchner reactions has been examined. When the 2-methoxysubstituted diazoketone 32 is subjected to rhodium(II) acetate catalysis, a single cycloheptatrienone 34 is obtained in 94% yield.10 This result is consistent with the outcome of the rhodium(II) trifluoroacetate-catalyzed intermolecular reaction of ethyl diazoacetate with anisole, which yields no product arising from addition of the ketocarbenoid on the most hindered site of the anisole. Dihydroazulenone 34 rearranges to tetralone 36 under acidic conditions, and isomerizes to the conjugated ketone 35 under basic conditions. It is interesting that the catalyzed decomposition of the paramethoxy derivative 37 provides exclusively 6-methoxy-2-tetralone 40 with no trace of the putative trienone 39. OMe

OMe Rh2(OAc)4 94%

EUN

Name Reactions for Carbocyclic Ring Formations

430

MeO

MeO

^Λ

MeO. Rh2(OAc)4 H 38

39

O

80% MeO 40

O

More highly substituted aromatics have also been studied in the course of natural product synthesis. For example, rhodium(II) mandelate-catalyzed cyclization of diazoketone 41 produces the ring expanded product 42, which on hydrogenations furnishes the tricyclic lactone 4 3 . "

H2, Pd/C; H2, Rh/Al203 ». 21%

The first direct chemical evidence for the formation of the norcaradiene system in the intramolecular Büchner reaction was obtained in the rhodium(II)-catalyzed decomposition of l-diazo-4-(2-naphthyl)butan-2-one 44.12 This reaction provides the tetracyclic norcaradiene 45 and tricyclic ketone 52 in 71% and 8% yield, respectively. When a catalytic amount of trifluoroacetic acid is added to 45, tricyclic ketone 51 is formed. It is surprising that compound 45 is recovered quantitatively after treatment with triethylamine in dichloromethane under reflux. The formation of 52 is explained in terms of an attack of the carbenoid carbon of 44 on the 2,3double bond of the naphthalene nucleus followed by double bond migration in the tricyclic nonconjugated ketone 49.

Chapter 5 Large-Ring Carbocycles

51

431

52 (8%)

The intramolecular cyclopropanation reactions of the aromatic ring in tetrahydronaphthyl diazomethyl ketones initiated by transition metal catalysts also afford stable norcaradiene products.13 These compounds are expected to be thermodynamically more stable than the tautomerie cyclohepatrienes because of the geometric constraints imposed by the bridging ring system. Indeed, decomposition of diazomethyl ketones 53 with rhodium(II) acetate affords 71% yield of the norcaradiene 54 along with 14% yield of the benzylic C-H insertion product, cyclopentanone 56 (vide infra). Several copper-based catalysts have also been evaluated, and a comparable result is obtained with Cu(II)(acac)2. These norcaradiene derivatives are valuable intermediates in natural product synthesis as they rearrange to polycyclic ring systems under various acidic conditions. For example, diketone 58 is obtained from norcaradiene 54 by treatment with aqueous hydrochloric acid, whereas on exposure to Lewis acids under anhydrous conditions, the initial fragmentation of the three-membered ring is followed by rearrangement to give tricyclic enone 61.

432

Name Reactions for Carbocyclic Ring Formations

^

MeO

MeO

MeO

56

Rh2(OAc)4 : 54 (71%), 56 (14%) Rh2(TPA)4: 54 (51%), 56 (38%) Cu(acac)2: 54 (61%), 56 (7%)

3MHCI 91% MeO

95%

MeO

MeO

A novel carbene insertion reaction in the Grubbs's second-generation catalyst 62a promoted by carbon monoxide has been described.14 The reaction pathway represents a novel carbene insertion into the mesityl group on the jV-heterocyclic carbene supporting ligand, a Büchner reaction of a ruthenium carbene. Treatrment of complex 62a with carbon monoxide immediately results in the formation of 63a in excellent yield. Similarly, the methylidene 62b gives a cycloheptatrienyl insertion product 63b in 63% yield. The Büchner reaction pathway can also be triggered by adding isocyanide ligands. The carbene insertion into the mesityl group is promoted by carbon monoxide binding. This binding causes the carbene to cyclopropanate the closest "double bond" of the mesityl group and electrocyclic ring opening of the resulting cyclopropane provides the cycloheptatriene. The high regioselectivity of the carbene insertion suggests that the carbene is still encumbered to the ruthenium centre and is not reacting as a free carbene.

Chapter 5 Large-Ring Carbocycles

R = Ph, 90% R = H, 63%

433

PCy3 63a/b

There are several examples of catalyzed aromatic cycloadditions leading to heterocyclic systems. The rhodium(II) acetate-catalyzed intramolecular Büchner reactions of jV-benzyldiazoacetamides 64a/b afford azabicyclo[5.3.0]decatrienes 66a/b in excellent yields.15 In contrast, the TVmethyl derivative 64c gives 66c in moderate yield. Use of rhodium(II) perfluorobutyrate (Rh2(pfb)4) in place of rhodium(II) acetate increases the yield to 54%. Unlike its carbon counterpart, dihydroazulenone 29a (vide supra), 66a is insensitive to either trifluoroacetic acid or boron trifluoride etherate, even in excess, and the unrearranged reactant is recovered intact even after prolonged treatment at room temperature.

Rh2(OAc)4

f^f(^tf 0

N2

- OJH.

65a/b/c

64a/b/c

O 66a/b/c

a: R = f-Bu, 100%; b: R = Bn, 93%; c: R = Me, 37%

Other heterocyclic systems formed via Büchner reactions include cycloheptafuranones 69. Thus diazoketones 67 with oc-phenoxy substituents undergo cyclization catalyzed by copper(II) bis(hexafluoroacetonate) to furnish mixtures of cycloheptafuranones 69 and chromanones 70.16 The product compositions depend on substituents in the precursors. These cycloheptafuranones rearomatize readily to chromanones 70 upon contact with silica gel. In addition to copper and rhodium, silver-catalyzed Büchner reactions have also been explored.17

434

Name Reactions for Carbocyclic Ring Formations

O

RVK

Cu(ll)

R2 O

67

68

-QK 69

R3 O

R1 = R2 = H, R3 = Me 65% yield (69/70 = 2/3) R1 = R2 = R3 = Me, 95% yield (69/70 = 9/1 ) R1 = R3 = Me, R2 = H, 95% yield (70 only) Ri = Ph, R2 = H, R3 = Me, 88% yield (70 only)

5. /. 5 Büchner Reaction vs. C-H Insertion Reaction Transition metal-catalyzed Büchner reactions of arene substrates proceed via electrophilic carbenoids. In addition to cyclopropanation of the arene double bond, these oc-diazoketones possessing an aromatic ring can also participate in C-H insertion reactions.18 As shown in the decomposition of diazomethyl ketone 53, the benzylic C-H insertion product 56 is obtained as a minor product (vide supra). The rhodium(II) acetate-catalyzed reaction of diazoketone 71 also affords cycloheptatriene derivative 73 along with the benzylic C-H insertion product, γ-lactam 72, in a ratio of 1:2.19 Treatment of 71 with the more electron-rich rhodium(II) caprolactamate [Rli2(Cap)4] favors more C-H insertion, but the cycloaddition pathway is still significant; the ratio of 73 to 72 is 1:3.5. N2<^

,Ph N

Rh(ll)

.Ph

JÖ

N BTMSM

BTMSM 71

72 Rh 2 (OAc) 4 , 99% yield Rh 2 (Cap) 4 , 97% yield

•CO-

~BTMSM

73

72/73 = 2/1 72/73 =3.5/1

Decomposition of 74 in the presence of rhodium(II) acetate gives stable norcaradiene 75, indicating that the electron-rich aromatic ring is more receptive than the enone moiety to attack by the ketocarbenoid.20 Introduction of a bromine substituent at C8 diverts carbene attack from the aryl ring, and insertion into the allylic C-H bond is now the preferred outcome. The suppression of the carbene addition to the benzenoid ring is expected since on both steric and electronic grounds the aryl ring becomes less reactive when it bears a bulky halogen.

Chapter 5 Large-Ring Carbocycles

U

MeO'

Rh2(OAc)4 — 52%

435

MeO

Rh 2 (OAc) 4 MeO

MeO

53%

The choice of transition-metal catalysts can play an important role in determining reaction pathways as shown in the model studies toward the synthesis of harringtonolide. The epimeric C-H insertion products 80 are obtained in 75% and 40-50%) yield, respectively, with Rh2(tpa)4 and rhodium mandelate. In contrast, bis(7v"-i-butylsalicyl-aldiminato) copper(II) generates the very labile cycloheptatriene 82 (50%> yield), which is converted to the more stable isomer 83 upon treatment with l,8-diazabicyclo[5.4.0]undec-7ene (DBU).21 Me i O.

NaOH; NaH; Me (COCI)2; A u CH 2 N 2

, , MeO-

70% OMe 80 bis(/V-t-Butylsalicylaldiminato) copper (II) O

79

78

DBU 50% OMe 83

OMe

OMe 82

81

436

Name Reactions for Carbocyclic Ring Formations

The a-(phenylsulfonyl)- and a-(ethoxyphosphoryl)-diazoacetamides 84d/e are exclusively converted to formal aromatic C-H insertion products 86d/e upon rhodium(II) perfluorobutyramide (Rh.2(pfb)2) catalysis. The unsubstituted diazoacetamide 84a affords exclusively the Büchner ring expansion product 85a, and the Büchner reaction remains the favorable pathway with diazo substrates 84b/c, which bear relatively small ocsubstituents. The predominant formation of the Büchner products in these cases can be rationalized on the basis of steric effects. Various isoquinolinones are synthesized intramolecularly via six-membered ring formation with high regioelectivity and diastereoselectivity, while averting the common Büchner reaction.

Rh2(pfb)4

84a-e

85a-« a: Z- = H 85% b: Z- = Ac 65% c: z--= C02Me 66% d: z-= S02Ph e: z-= P(0)(OEt)2

12% 15% 93% 86%

The rhodium(II) acetate-catalyzed decomposition of diazoamide 87 gives the benzylic C-H insertion product, the trans ß-lactam 90 (27% yield), together with the Büchner ring expansion product, the cycloheptapyrrolone 89 (5% yield).23 When rhodium(II) perfluorobutyramide is used as the catalyst, the aromatic C-H insertion proceeds exclusively to give indole 88 in excellent yield after silylation. In the case of the TV-benzyl diazoamide 91, a higher yield of the cycloheptatriene product is expected since the oxindole formation pathway is precluded. Indeed, the rhodium(II) acetate-catalyzed reaction of 91 gives the expected /ra«s-ß-lactam 93 (39%), together with its c/'s-isomer 94 (28%), and the cycloheptapyrrolone 92 (22%). Application of the prefluorobutyramide ligand favors attack on the double bond of the aromatic ring and gives the cycloheptapyrrolone 92 in good yield.

Chapter 5 Large-Ring Carbocycles N2^.C02Et

87

^

437 CO,Et

Rh2(pfb)4; TIPSOTf

OMe

OMe

Rh2(OAc)4

Meo

N

~OC ^ Et02C O 89 (5%)

+ MeO

90 (27%)

N2^X02Et

Rh2(OAc)4 Rh2(pfb)4

39% none

28% 12%

The Büchner reaction can be shut down by arene chromium tricarbonyl complexation.24 Thus benezenechromium tricarbonyl 95 and even electronrich /»ara-dimethoxybenzenechromium tricarbonyl (structure not shown) fail to react with ethyl diazoacetate and rhodium(II) trifluoroacetate. In contrast, the same reaction with benzene provides a single isomer of the cycloheptatriene in 98% yield. The Büchner reaction of pseudo-Ci symmetric substrate 97 clearly demonstrates the effect of chromium tricarbonyl complexation on arene cyclopropanation. Decomposition of diazoacetamide 97 with rhodium(II) acetate brings about exclusive addition

Name Reactions for Carbocyclic Ring Formations

438

to the noncomplexed ring to give lactam 98, with no addition to the complexed ring detected. Thus in both intermolecular and intramolecular Büchner reactions, chromium complexation protects arenes from cyclopropanation. Conceivably, the lack of activity of arene complexes toward carbenes arises from the electron-withdrawing nature of the chromium tricarbonyl moiety which is comparable to that of a nitro group. Carbene additions to electron-poor arene substrates are known to afford minimal, if any, the desired cyclopropanation products, with a propensity for benzylic C-H insertion reactions instead.

O

K 95

Cr(CO)3

EtO

OEt

Rh2(TFA)4 -N 2

"

not detected

96

Cr(CO) 3

Rh 2 (OAc) 4

76% 97

98

5.1.6 Macrocyclic Büchner Reactions Decomposition of diazoacetate 99a using rhodium(II) perfluorobutyrate in refluxing dichloromethane results in the formation of three aromatic cycloaddition products from reaction with the remote benzyl group at the 1,2-, 2,3-, and 3,4-positions in 75:12:13 ratio in 68% yield.25 This reaction is remarkabley free of byproducts including those from addition/substitution to the original benzenedimethanol unit or C-H insertion into the oxygen activated benzylic position. The /?ara-methoxybenzyl analog 99b also undergoes rhodium(II) perfluorobutyrate-catalyzed diazo decomposition to give two aromatic cycloaddition products, the major isomer of which (101b) results from addition to the 3,4-position of the benzylic group. This regiochemical preference is parallel to that of intermolecular aromatic cycloaddition to ^ara-disubstitiited benzene derivatives.

Chapter 5 Large-Ring Carbocycles

439

99a/b

a: R = H; b: R = OMe 100a/101a/102a = 75 : 12: 13 100b/101b/102b = 1 3 : 8 7 : 0

Rh2(OAc)4 68% (R = H) 85% (R = OMe)

Ώ>·

102a/b

100a/b

O Rh2(pfb)4 47% (R = H) 32% (R = OMe)

104

103a/b

a:R = H;b:R = OMe 105a/106a/106c = 31 : 21 : 48 ♦ 105a/106a/106c = 87:0: 13

ca> · K: 105a/b

106a/b

The analogous cw-2-buten-l,4-diyl derivatives 103a undergoes rhodium(II) perfluorobutyrate-catalyzed diazo decomposition to produce a moderate yield of three cycloheptatriene products resulting from addition to the 1,2-, 2,3-, and 3,4-positions of the benzene ring. The product ratio (105a:106a:107a = 31:21:48) is comparable to that obtained from intermolecular aromatic cycloaddition of ethyl diazoacetate to toluene catalyzed by rhodium(II) trifluoroacetate (18:24:58). It is interesting that

440

Name Reactions for Carbocyclic Ring Formations

cyclopropanation of the allylic double bond is not observed in reactions catalyzed by rhodium(II) perfluorobutyrate, but this occurs exclusively with rhodium(II) caprolactamate. With the />ara-methoxybenzyl analog 103b, both the product from aromatic cycloaddition to the 3,4-position and that from cycloaddition to the 1,2-position are obtained in 87:13 ratio in the rhodium(II) perfluorobutyrate-catalyzed reaction (32% yield). Diazoketones also undergo macrocyclic aromatic cycloaddition reactions. Decomposition of 108 with rhodium(II) prefluorobutyrate yields aromatic cycloaddition products 109 and 110 in 30% and 9% yield, respectively. When cycloheptatriene 109 is exposed to neutral alumina, isomerization to 111 occurs. It is interesting that the 1,4-isomer 110 is inert to rearrangement on both silica and alumina. The ability to formally connect a carbene to a remote aromatic ring provides new opportunities for the construction of macrocyclic compounds.

110(9%)

5.1.7

Tandem Alkyne Insertion/Buchner Reactions

The dirhodium tetra(triphenylacetate) (Rh2TPÄ4)-catalyzed decomposition of ethyl 2-diazo-3-phenylpropanoate in the presence of aryl alkynes yields the angularly substituted dihydroazulenes 115. The formation of 115 presumably takes place by a tandem alkyne insertion/Buchner ring expansion pathway via intermediates 112-114. The reactivity of aryl alkynes with 2diazo-3-phenylpropanoate is altered dramatically by changing the catalyst from dirhodium tetra(triphenylacetate) to dirhodium tetrapivalate (RI12PÌV4): cyclopropenes 116 are formed in 40-75% yields.

Chapter 5 Large-Ring Carbocycles ΞΕ^-ΑΓ

COoEt Rh2TPA4

441

AK

Ar

X02E t

[Rh]

Et0 2 C

112

Rh2Piv4

40-75%

C02Et

Ar.

A

7

116 115

o- - R h O- _ R h

Rh2Piv4 (R = f-Bu) Rh 2 TPA4(R = CPh3)

VY

σ

^ 1

Et0 2 C

5.1.8

113

114

Ar = Ph, 49% Ar

- > V ^ \s

w

C0 2 Et

66%

Asymmetric Büchner Reactions

Treatment of 117 with rhodium(II) acetate produces macrocyclic cyclopropene 119 in 69% yield. However, application of chiral catalyst Rh2(4ft-MEOX)4 to this system results in the cyclopropanation product 118 in 66% yield and 73% ee21

117 Rh 2 (OAc) 4 Rh 2 (4S-MEOX) 4

118

119

none 66% (73% ee)

69% none

The competition between ylide formation and aromatic cycloaddition has also evaluated. Decomposition of diazo acetate 120 in the presence of Rh2(45'-MEOX)4 leads to the sole production of the aromatic cycloaddition product 121 in 55% yield and 84% ee.

Name Reactions for Carbocyclic Ring Formations

442

OMe

OMe

C02Me N

2'

I

Rh2(4S-MEOX)4

Ó.

121 55% yield; 84% ee

120

A number of catalysts have been investigated for aromatic cycloaddition on the basic naphthalene system 122. In this case, Rr^^SIBAZ)4 is superior even to Rh2(4i?-MEOX)4 catalyst for highly enantioselective aromatic cycloaddition.

Rh2(4S-MEOX)4 Rh2(4S-IBAZ)4 122

123 Rh2(4R-MEOX)4: 76% yield; 56% ee Rh2(4S-IBAZ)4: 87% yield, 81 % ee

Asymmetric Büchner reactions using chiral auxiliary have also been undertaken.28 The diazoketo substrate 126 for the chiral tethered Büchner reaction is prepared from optically pure (2/?,4/?)-2,4-pentanediol in three steps: the Mitsunobu reaction with 3,5-dimethylphenol, esterification with diketene, and diazo formation/deacetylation. Treatment of 126 with rhodium(II) acetate results in a quantitative yield of 127 with more than 99% ee. This compound is reduced with lithium aluminium hydride, and the resulting diol 128 undergoes epoxidation and concurrent acetal formation to give 129 as a single diastereomer. Hydrogenation of 129 with Raney nickel proceeds stereoselectively to yield saturated diol 130, which is converted to aldehyde 132 via acid hydrolysis followed by oxidation. Compound 132 is a versatile intermediate for natural product synthesis.

443

Chapter 5 Large-Ring Carbocycles

Me,

-rr

Me

Me

OH OH

Me

Mitsunobu

OH

Me

Me O

ο=

OH

Et,N

98%

91% Me 124

Me Me Me

f

Me

rY o °γ-γ Μ Θ ~^ Me- ^ TsN 3 , NaOH

Me

o

Me

o

*Y^Y

'° °

K^ Me

125 Me /

•Me LiAIH4

Me

N2 Rh2(OAc)4 97%

o

126

N^.Me

\

γ

OH

mCPBA

95% ' M e ^ J p Q H

" ^

ΗΟ,,^,,ο

M e - ^ ^) OH 129

Me 128

\,„Me

Me

Me, RaNi

HO

y^V"Me

Hz0

HO

^>~\

T^T

Me-(

2vo

pTSA,

131

?

/V\

OH

Pb(OAc)4, MeOH *80%

Me

132

5.1.9 Synthetic Utility The power of the Büchner reaction, especially the intramolecular version, has been demonstrated in the syntheses of numerous natural products, and only a few representatives are described as below.

444

Name Reactions for Carbocyclic Ring Formations

Azulene(Pfaz-Plattner)29 and Substituted Azulenes (Danheiser)30 Azulene is an isomer of naphthalene, but their colors are different: azulene is dark blue, whereas naphthalene is a colorless. The name of azulene is derived from the Spanish word azul, meaning "blue." Derived from the German chamomile flowers (Matricaria recutita), azulene is known for its superior skin-soothing properties. Azulene has a long history, dating back to the 15th century as the azureblue chromophore obtained by steam distillation of German chamomile flowers. The chromophore was discovered in yarrow and wormwood and named in 1863 by Septimus Piesse. Azulene has been shown to be a highly effective anti-inflammatory and soothing agent, and it has been used professionally in topical applications for sensitive skin and in sun care and burn products, as well as calming face and body creams. The first chemical synthesis of azulene was reported by Pfau and Plattner in 1937. Their synthesis takes advantage of the ring enlargement of indane 133 on addition of diazoacetic ester to give cycloheptatriene 135. This compound is converted into azulene via a three-step sequence: hydrolysis, dehydrogenation, and decarboxylation of the resulting acid. N2CHC02R »- R02C 133

R0 2 C

134

fj ^ ^ — « . /T~%—\

~\^J^J 135

hydrolysis

de dehydrogenation;

-C02

azulene

Early approaches to the synthesis of azulenes, including the PfauPlattner approach involve low-yield dehydrogenation steps and are limited to the preparation of relatively simple azulene analogs. To this end, a ring expansion-annulation strategy for the synthesis of substituted azulenes has been developed, and this methodology is based on the reaction of ß-bromoα-diazo ketones with rhodium carboxylates. The key transformation involves the intramolecular Büchner reaction of diazoketone 136 followed by ß-elimination of the bromide 138, tautomerization and in situ trapping of the resulting 1-hydroxyazulene as a carboxylate 139 or triflate 140. This triflate undergoes various coupling reactions to provide the substituted azulenes 141.

445

Chapter 5 Large-Ring Carbocycles

Br

6-electron electrocyclic ring opening

Br

Rh2(OCOBu-f)4 (0.5-1 mol%)

^

rr

^ 138

137

136

DMAP, Tf2NPh

Suzuki coupling

140

DMAP 64-72% Ac 2 0 "

OTf

139

OAc

(±)-Confertin (McKervey, 1991)31 A formal total synthesis of confertin, a member of the pseudoguaianolide sesquiterpenoid family, employs the Büchner reaction to construct the sevenmembered ring moiety. Thus decomposition of diazoketone 143 with rhodium(II) mandelate in hot dichloromethane furnishes a single ringexpanded product consisting of an equilibrium mixture of bicyclic cycloheptatriene 145 and the tricyclic norcaradiene 143. This equilibrium mixture is reduced with lithium tri-féri-butoxyaluminium hydride to give a mixture of the epimeric alcohols 146 where norcaradiene moiety is absent. This alcohol is converted to confertin via a multistep sequence. Me

AC2O, K 2 C0 3 , ( 77%)

Rh(ll)

A c c r " - ^ ' H c r ^ o (coci2)2; ACO' 142

MeCHN2 (75%)

o 143 14J

N N

2

»100% Acer ^ 144

"Y" "-Ό Me

Li(t-BuO)3AIH

AcO

AcO 146

145

Hainanolidol and Harringtonolide (Mander, 1998)32 The diterpenoid tropone, harringtonolide, first isolated in North America from seeds of Cephalotaxus harringtonia (Taxaceae) and independently

Name Reactions for Carbocyclic Ring Formations

446 MeCX

H | 0 C0 2 Me

MeCX

J|yP° 2 M M e e [M^CHCirC,-; Me ) HO-if

Me 146 MeO

jj H ]0,C02Me ,,>'Me OR OMe *2 O 148

>-OR AOMe OMe 147

> 80%

MeO

rhodium mandelate

MeO.

MeO, DBU

H | 0 C0 2 Me ,.<Me

84% MeO

MeO

MeO.

-

151 ZnBr2 1 6 1 %

150 MeO, Al,0 2^3

C02Me Me

76%

K2C03

" 33%

152 MeO. H

I

Q

TBAF; NaBH4; HCI; base

Ph(OAc)4

hainanolidol

O harringtonolide

R = /-Pr(Et)2Si

Chapter 5 Large-Ring Carbocycles

447

from the bark of the related Chinese species Cephalotaxus hainanensis, has been shown to have promising antineoplastic and antiviral peoperties. In C. hainanensis, harringtonolide is accompanied by the closely related, but biologically inactive carbinol, Hainanolidol. Both diterpenoids were synthesized by Mander who constructed the tropone moiety via the intramolecular Büchner reaction of the diazo ketone 148. This diazo substrate is prepared by treating the sodium carboxylate of 147 with Vilsmeier reagent and adding the reaction mixture directly to an excess of diazomethane, affording 148 in 80% overall yield from 147. Cyclopropanation catalyzed by rhodium(II) mandelate furnishes an unstable adduci 150 that is immediately treated with l,8-diazabicyclo[5.4.0]undec-7-ene (DBU) to give the less labile cycloheptatriene 151 in 84% overall yield. Liberation of the aldehyde function from dimethyl acetal is carried out with zinc bromide, and the resulting aldehyde 152 undergoes intramolecular aldol reaction with basic alumina to give the desired aldol 153 in 76% yield. Treatment of 153 with potassium carbonate in aqueous methanol furnishes lactone 154 in moderate yield. Desilylation is effected smoothly with tetrbutylammonium fluoride (TBAF), and the ketone is reduced to diol, which, when briefly exposed to acid, affords hainanolidol in > 50% overall yield. Transannular oxidation of hainanolidol with lead tetraacetate generates harringtonolide. A drawback of the above-mentioned approach is the need to carry out multiple operations in the presence of the highly reactive cycloheptatriene moiety. An alternative route involves the assembly of the cycloheptatriene array to a much later stage.33 To this end, diazo ketone substrates 155 and 158 were prepared, but unfortunately, decomposition of both compounds in

155

158

156

R = TBDMS

159

157

160

Name Reactions for Carbocyclic Ring Formations

448

the presence of various Rh(II) and Cu(II) catalysts failed to deliver any desired Büchner reaction products Gibberellin (±)-GA,03 (Mander, 1997)34 Norcaradienes from intramolecular cyclopropanation reactions of diazomethyl ketones are valuable intermediates for the synthesis of polycyclic diterpenoids such as gibberellin (+)-GAio3, a representative of a family of hexacyclic gibberllins isolated in trace amounts from developing apple seeds. Decomposition of 161 with Cu(acac)2 affords norcaradiene 162, which undergoes Diels-Alder reaction with 3-methylfuran-2,5-dione 163 to give adduci 164 in 75% yield over two steps. Solvolysis of the anhydride function, in situ reduction of the ketone with sodium borohydride, and then hydrolysis of the enol ether during the acidic workup afford ketoacid 165. This acid is converted to the diazoketone 166 in three operations: iodolactonization, reduction of the iodide, and diazo-transfer reaction with trisyl azide. Wolff rearrangement of 166 proceeds smoothly, furnishing ester 167 in excellent yield. Gibberellin (±)-GAio3 is made from 167 in six steps. Me

o^ 0 ^-o 75%, 2 steps

NIS (65% from x) n-Bu3SnH(95%); ArS02N3 (66%)

C02Bn

c

Me

N2

166

0

79%

^CO C02Bn Me HC02Me 167

M'e

H

C02H

gibberellins GA103

Chapter 5 Large-Ring Carbocycles

449

5.1.10 Experimental 2,3-Dihydroazulen-l(4H)-one(30a)35 Rh2(OAc)4

27a

f| N2

°

CH2CI2,42°C

(/

\—v

Et3N

^ |f

69%

In a 750-mL, three-necked flask, equipped with an efficient condenser, thermometer, and nitrogen inlet, rhodium(II) acetate (52 mg, 0.12 mmol) was dissolved in dichloromethane (430 mL). The blue-green solution was heated under reflux (42 °C) under nitrogen, and a solution of l-diazo-4phenylbutan-2-one (27a, 37.8 g, mmol) in dichloromethane (10 mL) was added within 15 h via a syringe driven by a dosage pump, whereby the tip of the elongated hollow needle was placed in the refluxing solvent stream at the condenser. As a result of the very slow addition of l-diazo-4-phenylbutan-2one and the additional dilution by the refluxing solvent, an optimally high dilution effect for the catalyzed intramolecular Büchner reaction could be attained. After the addition of l-diazo-4-phenylbutan-2-one was complete, the resulting solution was heated under reflux for another hour and then cooled to room temperature. A small amount of triethylamine (0.20 mL) was added, which caused a transitory darkening from yellow to brown and spontaneous warming of the solution to 40 °C. Finally, the initial yellow color returned. After 30 min, the solution was filtered over silica gel, and the solvent was removed by distillation, and the yellow residue was purified by silica gel chromatography eluting with hexanes/M3uOMe (5:1) to give a greenish yellow oil, which was recrystallized from hexanes//-BuOMe (20:1) to give (5Z,7Z)-2,3-dihydroazulen-l(4/f)-one (30a) as colorless needles (21.87 g, 69%). 5.1.11 References 1.

2. 3. 4. 5.

[R] (a) Marchard, A. P.; Brockway, N. W. Chem. Rev. 1974, 74, 431. (b) Ye, T.; McKervey, M. A. Chem. Rev. 1994, 94, 1091. (c) Padwa, A.; Krampe, K. E. Tetrahedron, 1992, 48, 5385; (d) Doyle, M. P.; McKervey, M. A.; Ye, T. Modern Catalytic Methods for Organic Synthesis with Diazo Compounds, Wiley, New York, 1998; Ch. 6. (d) Davies, H. M. Comprehensive Organic Synthesis, Trost, B. M., ed.; Pergamon, Oxford, 1991, Vol. 4, Ch.4.8. [R] (a) Jaenicke, L. Angew. Chem., Int. Ed. 2007, 46, 6776. (b) Stryer, L. Biochemistry, 4,h ed. Freeman, New York, 1999, pp. 484-484. Curtius, T. Ber. Dtsch. Chem. Ges. 1883,16, 2230. von E. Doering, W.; Knox, L. H.. J. Am. Chem. Soc. 1957, 79, 352. Anciaux, A. J.; Demonceau, A.; Noels, A. F.; Hubert, A. J.; Warin, R.; Teyssie, P. J. Org. Chem. 1981, 46, 873.

450 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18. 19. 20. 21. 22. 23. 24. 25. 26. 27. 28. 29. 30. 31. 32. 33. 34. 35.

Name Reactions for Carbocyclic Ring Formations [R] Carey, F. A.; Sundberg, R. J. Advanced Organic Chemistry, Part B, 3rd ed. Prenum Press, 1990, pp. 522-528. Yang, M.; Webb, T. R.; Livant, P. J. Org. Chem. 2001, 66,4945. (a) Scott, L. T. J. J. Chem. Soc., Chem. Commun. 1973, 882. (b) Scott, L. T.; Minton, M. A.; Kirms, M. A. J. Am. Chem. Soc. 1980,102, 6311. Kennedy, M.; McKervey, M. A.; Maguire, A. R.; Tuladhar, S. M.; Twohig, M. F. J. Chem. Soc, Perkin Trans. 11990, 1047. Cordi, A. A.; Lacoste, J.; Hennig, P. J. Chem. Soc, Perkin Trans. 11993, 3. Duddeck, H.; Ferguson, G.; Kaitner, B.; Kennedy, M.; McKervey, M. A.; Maguire, A. R. J. Chem. Soc, Perkin Trans. 11990, 1055. Manitto, P.; Monti, D.; Speranza, G. J. Org. Chem. 1995, 60, 484. Morris, J. C; Mander, L. N.; Hockless, D. C. R. Synthesis 1998, 455. Galan, B. R.; Gembicky, M.; Dominiak, P. M.; Keister, J. B.; Diver, S. T. J. Am. Chem. Soc. 2005,127, 15702. Doyle, M. P.; Shanklin, M. S.; Pho, H. Q. Tetrahedron Lett. 1988, 29, 2639. Pusino, A.; Saba, A.; Rosnati, V. Tetrahedron Lett. 1986, 42, 4319. Lovely, C. J.; Browning, R. G.; Badarinarayana, V.; Dias, H. V. R. Tetrahedron Lett. 2005, 46,2453. For a review on rhodium-mediated intramolecular C-H insertion, see Taber, D. F.; Stiriba, S. Chem. Eur. J. 1998, 4, 990. Wee, A. G. H.; Duncan, S. C. Tetrahedron Lett. 2002, 43, 6173. White, J. D.; Hrnciar, P.; Stappenbeck, F. J. Org. Chem. 1999, 64, 7871. Zhang, H.; Appels, D. C; Hockless, D. C. R.; Mander, L. N. Tetrahedron Lett. 1998, 39, 6577. Park, C. P.; Nagle, A.; Yoon, C. H.; Chen, C; Jung, K. W. J. Org. Chem. 2009, 74, 6555. Miah, S.; Slawin, A. M. Z.; Moody, C. J.; Sheehan, S. M.; Marino, J. P. Jr.; Semones, M. A.; Padwa, A.; Richards, I. C. Tetrahedron 1996, 52, 2489. Merlic, C. A.; Zechman, A. L.; Miller, M. M. /. Am. Chem. Soc. 2001, 123, 11101. Doyle, M. P.; Protopopova, M. N.; Peterson, C. S.; Vitale, J. P. J. Am. Chem. Soc. 1996, 118, 7865. Panne, J. M.; Fox, J. M. J. Am. Chem. Soc. 2007, 129, 22. Doyle, M. P.; Ene, D. G.; Forbes, D. C; Pillow, T. H. J. Chem. Soc, Chem. Commun. 1999, 1691. Sugimura, T.; Im, C. Y.; Sato, Y.; Okuyama, T. Tetrahedron 2007, 63,4027. Pfau, A. S.; Plattner, P. A. Helv. Chim. Ada. 1939,22, 202. Crombie, A. L.; Kane, J. L. Jr.; Shea, K. M.; Danheiser, R. L. J. Org. Chem. 2004, 69, 8652. Kennedy, M.; McKervey, M. A.; Maguire, A. R. J. Chem. Soc, Perkin Trans. /1991, 2565. Frey, B.; Wells, A. P.; Rogers, D. H.; Mander, L. N. J. Am. Chem. Soc. 1998,120, 1914. O'Sullivan, T. P.; Zhang, H.; Mander, L. N. Org. Biomol. Chem. 2007, 5, 2627. King, G. R.; Mander, L. N.; Monck, N. J. T.; Morris, J. C; Zhang, H. J. Am. Chem. Soc. 1997, 119, 3828. Rüedi, G.; Hansen, H. Helv. Chim. Ada. 2001, 84, 1017.

Chapter 5 Large-Ring Carbocycles

5.2

451

de Mayo Reaction

Yong-Jin Wu 5.2.1

Description

The de Mayo reaction is a sequence of reactions involving the photocycloaddition of an olefin with an enol or enol derivative of a ß-dicarbonyl compound, followed by a retro-aldol fragmentation reaction to give a 1,5diketone. R1 3

R O^R

5.2.2

4

■c-

R 1 n2 hv

^.

R30"T7^R6

R1

^2

0=f^R6 R4

Historical Perspective

The photochemical [2 + 2] cycloaddition of two alkenes to generate a fourmembered ring is a powerful and general method in organic synthesis. The discovery of this reaction started with the work of Ciamician/Silber1 and Stobbe2 more than a century ago when they investigated the photochemistry of stibene and styrene derivatives. The most well-known example of their work is the photodimerization of cinnamic acid to the truxinic and truxillic acids. In 1908, Cimician also observed that exposure of carvone to Italian sunlight for 1 year led to the formation of carvonecamphor.3 This conversion represents the first example of an intramolecular enone-olefin photocycloaddition. It is surprising that very little attention was paid to this type of reaction until Buchi confirmed the carvone photoisomerizationin in 1957.4 One year later, Cookson reported that irradiation of the endo DielsAlder adduct 1 derived from cyclopentadiene and para-benzoquinone, generates the cage structure 2 via an intramolecular [2 + 2] photocycloaddition.5 In 1964, Eaton completed the synthesis of the platonic solid, cubane, using the intramolecular enone-olefin photocycloaddition of intermediate 3 to give compound 4.6 The intramolecular version of this reaction was first applied to the total synthesis of a natural product in 1968 by Wiesner who prepared 12-epilycopodine.7 In the meantime, Corey, Eaton, de Mayo, and others examined intermolecular enone-olefin photocycloadditions. In 1962, Eaton reported

452

Name Reactions for Carbocyclic Ring Formations

the photocycloaddition of 2-cyclopentenone to cyclopentene to give adduci 5.8 In 1964, Corey disclosed the [2 + 2] photocycloadditions of 2cyclohexenone to a variety of alkenes and established many of the characteristic features of this reaction.9 The potential of this type of enoneolefin reactions was first shown by Corey in his landmark syntheses of dlcaryophyllene and c//-isocaryophyllene in 1963, and α-caryophyllene alcohol in 1964.10·11 In 1962, de Mayo reported an ingenious application of the intermolecular enone-olefin photocycloadditions by irradiating ß-diketones in the presence of olefins to generate 1,5-diketones. This reaction, which is now known as the de Mayo reaction,13 proceeds through the enol of a 1,3diketone (e.g., pentane-2,4-dione), which exists rigidly in a six-membered ring by an intramolecular hydrogen bond (e.g., 7). Photoaddition of an olefin (e.g., cyclohexene) to this enol leads to a ß-hydroxy ketone (e.g., 8), which undergoes spontaneous retroaldolization to give a 1,5-diketone product (e.g., 9). The synthetic power of this reaction was not fully realized until the late 1970s when Oppolzer, Pattenden, and others, reported the facility with which complex macrocyclic structures can be constructed via an intramolecular photoaddition sequence.130'138 Over the years, the de Mayo reaction has been extended to vinylogous esters and amides and dioxolenones as ß-keto ester equivalents. These developments have culminated in the total syntheses of complex natural products, including saudin, ingenol, vindorosine, and manzamine A by Winkler.13h In fact, Winkler's approach to manzamine using intramolecular photocycloaddition of vinylogous amides has been recognized as a classic piece of total synthesis.14 The de Mayo reaction resulted from his extensive contribution to photochemistry during the 1960s and 1970s. Paul Jose de Mayo (19241994)15 completed his Ph.D. in organic chemistry at the Birkbeck College in 1954 under the supervision of Nobel Laureate D. H. R. Barton. In 1955 and 1957, he moved with Barton to the University of Glasgow and Imperial College, respectively, and served as a lecturer. The introduction of photochemistry in his research during this time would prove to be pivotal in his career, de Mayo conducted postdoctoral studies with Nobel Laureate R. B. Woodward at Harvard (1958-1959). He started his independent research career at the University of Western Ontario in 1959, and 3 years later, he discovered the de Mayo reaction. In his university, he founded a photochemistry department unit that contributed over 500 papers to the field. Ph-CH=CH-C02H Ciamician, 1902

hy_

Phv H0 2 C^

+ X

C0 2 H

HOzC^ Ph-"

,Ph ^C0 2 H

453

Chapter 5 Large-Ring Carbocycles

Me.

Me H i Me V^-T^O

hv ,Me

Ciamician, 1908

carvonecamphor

canzone

hv

V

Cookson, 1958

O \

Br

^x — °irf (f* Br

o

O

cubane

H H

Me H \_ " Me'

hv

Me

o

Me'

Corey, 1963

Me

CT~Me

Me

7

Me O

Me O

H O

j f j Me

de Mayo, 1962

H

Me

isocaryophyllene

Me

?

Eaton, 1964

Eaton, 1962

o

Y

I44J

H H

hv

». 67%

Mev Me

"*

OH

Me

454

Name Reactions for Carbocyclic Ring Formations

5.2.3 Mechanism ofPhotoadditions130^16 The photocycloaddition process is still not well understood, and a proposed mechanism is briefly discussed here. Excitation of the ground state enone probably via n —» π* produces the excited singlet, which undergoes intersystem crossing to either an n - ) i * or π—> π* excited triplet. The next step is the complexation of the triplet state with the olefin to form an exciplex. Even though this exciplex has not been yet directly observed, it is consistent with the regiochemistry of some intermolecular photocycloaddition reactions and the observation that photocycloaddition reactions are much faster than those of normal radical additions to olefins. The exciplex is collapsed to a 1,4-diradical, and this process may involve initial bond formation at either C a or Cß of the enone. Finally, the triplet 1,4-diradical must undergo spin inversion to the singlet diradicai before ring closure to form the cyclobutane. Stereospecificity is lost if the intermediate 1,4diradical undergoes bond rotation faster than ring closure. As a result, photocycloadditions are not always stereospecific.

Enone

hv

-

,

1

[Enone]*

intersystem crossing

Cyclobutane

-

-

, Olefin ^Enone]* -

1,4-Diradical

-

J

[Enone....Olefin]*

spin inversion

3

[1,4-Diradicalj

5.2.4 Regioselectivity of PhotocycloadditionsUing In the intermolecular photocycloadditions of enones to unsymmetrical alkenes, the regiochemistry of the product may result from head-to-head or head-to-tail addition. In many cases, however, a mixture of both types of these regioisomers is formed. Unfortunately, regiospecificity in [2 + 2] intermolecular photocycloadditions does not follow a simple rule. ' In contrast, ß-dicarbonyl compounds or their enol derivatives bearing appropriate olefin moieties undergo highly regioselective intramolecular photocycloadditions. The regioselectivity of the intramolecular photocycloaddition is generally high in systems where the two double bonds are separated by two, three, or four atoms. Formation offive-memberedrings is preferred, and if a five-membered ring cannot be formed, then formation of six-membered systems is favored. This observation is termed "rule of fives" by Hammond and Srinivasan,19 and is similar to the observation by Beckwith that 5-hexenyl radical undergoes cyclization to the cyclopentylmethyl radical

Chapter 5 Large-Ring Carbocycles

455

75 times faster than to the cyclohexyl radical. Since the intramolecular de Mayo reaction is much more widely utilized in organic synthesis than the intermolecular version, the former is the focus of this review. ß-Diketones and Their Derivatives

5.2.5

Classic de Mayo Reactions The classic de Mayo reaction involves the [2 + 2] photocycloaddition of an alkene to the hydrogen-bonded enol tautomer of a β-dicarbonyl compound as exemplified by the formation of 1,5-diketone 9 from pentane-2,4-dione and cyclohexene (vide supra). In addition to alkenes, allenes are also used as the olefmic component. For example, irradiation of a mixture of dimedone and aliene results in the formation of 3,3-dimethyl-7-methylenecycloocta-l,5dione 12 via the cyclobutane intermediate 11, together with the corresponding head-to-tail product 13, which spontaneously dimerizes to the hetero Diels-Alder adduct 14.21 Diketone 12 is a versatile building block for the preparation of substituted cyclooctadienones and δ-valerolactones.

+

·

rm

43%

^—\Me

Me

14

^—ζ O

40%

Me

12

\ O

The intramolecular de Mayo reaction using an isocarbostyril substrate with a functionalized tether on nitrogen is employed in the synthesis of the galanthan ring system. Irradiation of 15 in acetonitrile gives a single product 18 in good yield.22 Ring closure to the galanthan skeleton is carried out under basic conditions with piperidine to generate ketone 19 in 78% yield.

Name Reactions for Carbocyclic Ring Formations

456

Me^O

Me^CL V

Me^^O

OH

ϊιυ 70% 0

0

16

17

piperdine

18

Enol Esters of ß-Diketones Both enol esters and enol ethers (vinylogous esters) undergo similar intramolecular photocycloaddtions, but enol esters have advantage over enol ethers in terms of fragmentation process. Fragmentation of the cyclobutane photoadducts from enol esters is conveniently carried out under basic conditions, whereas that from enol ethers often requires additional operation to convert ether to ester or lactone (vide infra). For this reason, enol esters are more widely used than enol ethers. Photoaddition of enol acetate 20 produces the straight adduct 21 in high 23 24 This regiochemistry is consistent with the general preference for yield. ' the formation of five-membered rings when possible. Adduct 21 is fragmented under basic conditions to generate diketone 22.

OAc

hv

,Θ OH

89%

48%

Photocycloaddtion of the cyclopentyl derivative 23 also proceeds regioselectively to give the eis- and /raws-cyclobutane 24 and 25 in 70% and 12% yield, respectively. Base-induced fragmentation of both isomers furnishes a single diketone 26 in excellent yield.

Chapter 5 Large-Ring Carbocycles

457

KOH AcO H

24

AcO H

25 12%

70%

97%

f"H 26

An exception to the rule of fives is observed in the case of enol acetate 27.23 In contrast to 23, irradiation of the cyclohexenyl substrate 27 gives the tricyclic ketoacetate 31 as the major product and the expected tetracyclic photoadduct 30 as the minor product. The major product probably arises from hydrogen atom abstraction pathway via the 1,4-diradical intermediate 29, whereas the pathway to the minor adduci 30 may involve the radical intermediate 28. Presumably, there is significant geometric strain in the transition state for the initial cyclization to 28, therefore the alternative initial cyclization to 29 is favored. Exposure of adduct 30 to basic conditions brings about saponification followed by retro-aldol fragmentation to give tricyclic diketone 32.

hv

25% KOH 82%

32

Irradiation of enol acetate 33 produces a 2:3 ratio of 36 to 37.25 The poor regioselectivity observed in this case is not entirely unexpected, since there is little stability difference between the anticipated seven-membered and eight-membered biradical intermediates, 34 and 35, respectively. Both adducts 36 and 37 are fragmented under basic conditions to the bicyclic compounds, 38 and 39, respectively.

Name Reactions for Carbocyclic Ring Formations

458

47%

35

34

33

e

Θ EtO

EtO

36

38

2:3

OEt

37

39

The regioselectivity of photoaddition of the enol acetate of 40 depends on reaction temperature, and the ratios of 41 to 42 are 11:89, 2:3, and 51:49 at -70 °C, 25 °C, and 65 °C, respectively.25'26 Of note is that the acetylation of 1,3-diketone 40 is not regiospecific, but the two enol acetates interconvert via a photo-Fries process. However, only the enol acetate leading to 41 and 42 participates in the cycloaddition. Fragmentation of adducts 41 and 42 gives diketone 44 and the aldol product 45 via diketone 43. Ac 2 0; hv

c '-αβ- LPT1 \U ÖAc 41

OAc 42

KOH ■

n

0=

43

KOH

85% ,0

44

In contrast to the enol acetate of diketone 40, the methyl-substituted enol acetate 46, undergoes photocycloaddition to give exclusively the straight adduct 49.27 This has been explained on the basis of a steric interaction between the methyl group and the cyclopentane methylene hydrogens in the exciplex 48. This interaction is much reduced in exciplex 47.

Chapter 5 Large-Ring Carbocycles

459

hv ~Me

OAc 46

47 83%

1—f-Me

AcO

Me

50 none

Irradiation of enol acetate 51 affords the exclusive straight adduci 52 as a 3:1 mixture of methyl epimers.27 Base-induced fragmentation and subsequent spontaneous retroaldolization-realdolization sequence generates 54, which has been converted to daucene. .Θ OH

ηυ 88%

100%

3 steps

/-Pr,

The 1,7-dienes 55 undergo highly regioselective cycloaddition to give 56 whether R is H or Me.28 Both substrates afford the straight adducts 56 exclusively, the general tendency for 1,7-dienes, since the formation of a sixmembered ring is preferred over seven-membered ring. Treatment of 56 with aqueous potassium hydroxide gives the tricyclic alcohol 58, the result of a tendem reiro-aldol/intramolecular aldol reaction sequence.

Name Reactions for Carbocyclic Ring Formations

460

^

ηυ

88%

AcO^^ 55

AcO

R = H, Me

KOH

56

Me 57

100%

58

Regioselective photocycloaddition of enol carbonate 59 with aliene results in the formation of adduct 60 in 83% yield.29 The protecting group is removed under palladium-catalyzed conditions, and the resulting alcohol undergoes retro-aldol reaction and olefin isomerization to give the 1,5diketone 62 in excellent yield. This compound contains the AB ring system of the taxane skeleton. 97% 83% 59 R = C02allyl

"°

RO

Pd(0) 60

KOH EtOH

Vinylogous Esters Intramolecular de Mayo reactions have also been carried out on vinylogous esters of cyclic 1,3-diketones, and the adducts can be fragmented under appropriate conditions. Thus irradiation of the vinylogous ester 63 furnishes the crossed product 64,30 which, upon gentle warming in water, fragments to

Chapter 5 Large-Ring Carbocycles

461

ketoalcohol 65 in 53% yield.31 It is interesting that when the geminai dimethyl substituted analog 66 is irradiated under similar conditions, the expected photoadduct is not formed, and instead the bicyclic ketone 67 is obtained.3 The formation of 67 may be considered as a photochemical version of the intramolecular "ene" reaction. The 1,6-diene 68a undergoes photocycloaddition in accord with the rule of fives to give the straight adduct 69a. When this adduct is treated with BF3-Et20 followed by aqueous workup, cyclooctanedione 70 is generated. The photocycloaddtion of the homologous 1,7-diene 68b also gives the straight adduct 69b.33

The photocycloaddtion/fragmentation approach of vinylogous esters has been applied to the synthesis of the BC ring system of the taxane skeleton. Photocycloaddition of 71 generates a 47% yield of the single diastereomer 72, which is converted to the rc-propyl-substituted cyclobutane derivative 73 using three operations.34 This cyclobutane is cleaved with trimethylsilyl triflate to give the silylenol ether 74, which is further hydrolyzed to the tricyclic ketone 75. Treatment of 73 with acid leads directly to 75 in a slightly lower yield. Alternatively, the tetrahydrofuran moiety of 73 is oxidized with RuC>4 to afford the lactone 76, which is saponified with concomitant cyclobutane cleavage to give the bicyclic 1,5diketone 77. This diketone resembles the BC ring system of the taxane

462

Name Reactions for Carbocyclic Ring Formations

skeleton, and the whole skeleton has also been constructed using a similar strategy (vide infra). H Me

hx> 47%

LDA, allyl bromide; heat; H2, Pd/C

ò-o° x

Me'

72

n-Pr

TMSO

TMSOTf n-Pr^J^^p^ 84%'o

Me^^=^J Me

74

HCI 100%

0-o°

n Pr

"

Me Me

HCI, H20, heat, 70%

n-Pr.

DMSO, NaOH

n-Pr Me' Me

69% (2 steps)

il H O C02H 77

In contrast to cyclopentenones and cyclohexenones, medium-ring vinylogous esters are not suitable for photocycloaddition reaction unless the olfin coupling partner is substituted. For example, when (£)-3-(but-3enyloxy)cyclooct-2-enone 78a is irradiated under a variety of conditions, no intramolecular cycloadduction occurs. However, upon substitution of a vinyl or phenyl on the olefin, the cycloaddition proceeds efficiently to give diastereomeric mixtures 79b/c, and 80b/c, respectively. The dramatically enhanced yields and rates of the photoaddition reactions upon olefin substitution result from the stabilization of the 1,4-biradical by a vinyl or phenyl. A mixture of diastereomers is formed presumable because the rotational relaxation of the intermediate 1,4-diradical is faster than [2 + 2] ring closure. I f

Chapter 5 Large-Ring Carbocycles

463

78a/b/c

The intramolecular photoaddition of vinylogous esters with allenes has also been explored.36 Thus photocycloadition of 82 leads to the formation of the bicyclic furan 84 in moderate yield. This furan derivative is prepared from the cyclobutane intermediate 83, which results from the parallel addition to the terminal olefin of the aliene. However, this approach does not work for the acyclic vinylogous ester 85. Irradiation of this ester provides none of the expected furan product 87 and results only in isomerization of the vinylogous ester.

hv

0 II

re 0

83 H

A

Me-

oJ 85

hv

J

A_

Me'

O. 86

87

not observed

464

Name Reactions for Carbocyciic Ring Formations

Vinylogous Amides (Aza-de Mayo Reaction)37 Vinylogous amides undergo a similar sequence to the classic de Mayo reaction with the exception that the intermediate cyclobutanes cleave via re/ro-Mannich pathway rather than a retro-aldol process. The photocycloaddition/reiro-Mannich reaction of vinylogous amides is sometimes referred to as the αζα-de Mayo reaction in the literature. For example, photolysis of 88 leads to the exclusive formation of the crossed photoadduct 89 in 50-60% yield.32'38 Zte/roMannich fragmentation of 89 proceeds readily in refluxing water to give a 94% yield of an equilibrium mixture of tautomers: ketoaminal 91, diketoamine 90, and keto imminium ion 92. When the geminai dimethyl substituted substrate 93 is irradiated, none of the desired aza-de Mayo product is obtained, and instead the unusual "photochemical ene product" 94 is isolated as the sole product in 66% yield.

H20

*■ Me

\

50-60%

89

/ N Me

94%

Me Me' NHMe

hv 66% 94

Irradiation of 95 gives the reiro-Mannich fragmentation product 1,5ketoimine 97, presumably through the intermediacy of the straight the photoaddition adduci cyclobutane 96.39 When the linking unit is shortened,

Chapter 5 Large-Ring Carbocycles

465

photo-aza-Claisen rearrangement competes with photocycloaddition.40 Thus photocycloaddition of 98 provides a mixture of two compounds, the photoίζζα-Claisen rearrangement product 101, and the 1,5-ketoimine 100. This imine derives from the straight photoaddition intermediate 99; it is surprising that no keto imine 103 (resulting from the crossed adduct 102) is formed. This appears to be an exception to the rule of fives. Of note is that the structural assignment of ketoimine 100 (based on NMR and IR data) has not yet been confirmed by X-ray studies. It is interesting that the TV-methyl derivative 104 leads to a mixture of the photo-oza-Claisen rearrangement product 106, and the photoadduct 105 via cross addition, according to the rule of fives.

ηυ

Me Me HN

Me Me HN 95

ηυ

[2 + 2]

ηυ

aza-Claisen

\

Me^7\ N ^102

103 not observed

ηυ

[2 + 2]

Me-

M<£ ~

105

106

NHMe

466

Name Reactions for Carbocyclic Ring Formations

The highly substituted 7V-alkenoyl ß-enaminone 107 undergoes photocycloaddition to give the tetracyclic adduct 108 as a single diastereomer.41 Fragmentation of the photoadduct 108 using hydrochloric acid in aqueous dioxane affords the fused bicyclic ring system 109 in 60% yield.

HCI

hv

Me

77%

M

é ^ ^.N Bz

60%

H

108

107

109

NHBz

The appropriately substituted vinylogous amides can undergo an intramolecular photocycloaddition-reiro-Mannich-Mannich sequence. This sequence is analogous to the photocycloaddition-reiro-aldol-aldol sequence shown in the formation of 19 from 15 (vide supra). Thus, irradiation of 110 leads to the formation of ketoimine 112, the product of photoaddition followed by retro-Mannich fragmentation. Reaction of 112 with 1 equiv of trimethyloxonium tetrafluoroborate, followed by treatment of the resulting iminium ketone with aqueous hydrochloric acid, provides the photocycloaddition-re/ro-Mannich-Mannich product 113 in 50% yield from the acyclic photosubstrate 110.42

o

M e hx>

110

Λ

^,e

,NH

N

Me

111

112

© Θ Me 3 0 BF 4 50% from 110

113

The photocycloaddition-retro-Mannich-Mannich methodology is featured in a concise synthesis of mesembrine.42 Irradiation of vinylogous amide 114 effects photocycloaddition-re/ra-Mannich sequence to give product 116 via the cyclobutane intermediate 115. Methylation with trimethyloxonium tetrafluoroborate followed by treatment with DMAP produces mesembrine in 84% yield. Other applications include construction of the bicyclic core of peduncularine43 and synthetic approaches to hetisine alkaloids44aand 8-substituted 6-azabicyclo[3.2.1]octan-3-ones.44b

467

Chapter 5 Large-Ring Carbocycles ci

Λ

Ar-

© Θ Me30 BF4

74%

Me

\ NH

84%

115

Ar =

^

//

-OMe

OMe mesembrine

Intramolecular photoaddition of vinylogous imide 117a results in the formation of the bridged bicyclic compound 120a in 52% yield. This compound is generated via the crossed photoaddition of 117a to generate intermediate 118a. This intermediate then undergoes re/ro-Mannich fragmentation to afford zwitterionic intermediate 119a, cyclization of which provides the observed product 120a. The JV-BOC protected photosubstrate 117b undergoes the same transformation, but the corresponding JV-BOC product 120b is unstable to purification. However, when vinylogous amides 121 are irradiated, only pyrroles 124 are obtained. These pyrroles are formed via the intermediacy of cyclobutanes 122 resulting from the parallel addition to the terminal olefin of the aliene. This represents the first example of parallel intramolecular photocycloaddition to the terminal olefin of an aliene. Similarly, irradiation of cyclohexane-l,3-dione-derived vinylogous amides 125 affords pyrrole products 126 in excellent yields, but it is surprising that only moderate yield of pyrrole 128 is obtained from the corresponding cyclopentenone 127. Me

O hv

Me

J

RN 117a/b

HO

Me RN-

:

= Ac

? 5 b:R = Boc

Me

-no /u 118a/b

\\ R 119a/b

V 120a/b

Name Reactions for Carbocyclic Ring Formations

468

A O

Me'

J

RN

121 R = H,Me

X

HN

J

125

5.2.6

87%(X=H)

RN

77%(X = Me)

.

^

13h

ß-Keto Ester Derivatives

The photochemical reactivity of ß-ketoesters is different form that of ßdiketones.13h Irradiation of a ß-ketoester in the presence of an alkene produces oxetane via the ketone carbonyl instead of the desired cyclobutane ring system. Therefore, it is necessary to covalently "lock" the ketoesters as the enol tautomers. To this end, silyl enol ethers, 129 and 132a, and enol acetates, 130 and 132b, were prepared, but these substrates still fail to undergo the desired intramolecular [2 + 2] photocycloaddition with olefins. The only new products observed in these reactions result from the photoFries rearrangement of the cyclic enol acetate (130 to 131) and cis-trans isomerization of both acyclic substrates 132a/b. However, tetronates are appropriate substrates for both intermolecular and intramolecular photocycloadditions with olefins. In addition, enol acetates and silyl enol ethers of ß-keto esters are known to undergo [2 + 2] photoaddition with cyclic enones (vide infra). OTMS C02Me

C02Me

130

hv

No Reaction

hv 131

Chapter 5 Large-Ring Carbocycles

469

OR hv

132a/b

cis-trans isomerization

a: R = Ac b: R = TMS

Dioxolenones as ß-Keto Ester Equivalents In 1980, Baldwin developed a modification of the de Mayo reaction using dioxinone heterocycles as covalently locked enol tautomers of ß-keto esters.45 Thus intermolecular cycloaddition of 2,2,6-trimethyl-l,3dioxolenone 133 occurs in good yield using stoichiometric quantities of a variety of alkenes. For example, irradiation of 133 with tetramethylethylene yields the cyclobutane adduct 135 in 90% yield. This adduct is converted to cyclohexenone 138 in two steps. Controlled reduction of 135 with diisobutylaluminum hydride (DIBAL) gives keto aldehyde 137 (after spontaneous loss of acetone from hemiacetal 136 and retro-aldol cyclobutanol fragmentation), which on exposure to acidic conditions affords cyclohexenone 138 in 76% yield.

Me

I

M e ^ ^Me

hv

Me

90%

134

133 HO

o ^

Me Me

Me

Me Me

MeMe 136

DIBAL

135

H Me Me Me

H Me -Me -Me crX Me Me

o ^

pTSA

Me^/V- Me

T Me

76%

O

137

138

2,2-Dimethyl-4//-l,3-dioxin-4-one 139 has been used as the photochemical equivalent of formylacetate, which is inactive as the enone partner in the photoaddition with alkenes. Irradiation of dioxinone 139 in the presence of symmetrical cyclopentene 140 leads to the cyclobutane adduct 141. This intermediate upon subjection to hot water undergoes retro-aldol fragmentation and spontaneous lactonization to give lactone 143, a useful prostaglandin intermediate.46 Enantiomerically pure lactone 143 is prepared by using a chiral version of dioxinone 139.47

Name Reactions for Carbocyclic Ring Formations

470

OH

à

H?0

hv

OH

139

141

140 OH

/

X

30%

H02C "S^A IHC-ΤΥ OHC H OH

Q OHC

142

143

Like enol derivatives of ß-diketones, the regiochemical outcome of the intermolecular cycloaddition of dioxolenone substrates with unsymmetrical alkenes can be difficult to predict on the basis of existing enone photocycloaddition prediction models. The intramolecular version of the dioxinone photocycloaddition reaction, however, provides greater regiochemical control. For example, photocycloaddition of 143 occurs regioslectively to afford the desired crossed adduci 144 as a single diastereomer in excellent yield.48 Treatment of this adduci with aqueous potassium hydroxide brings about selective saponification of the sixmembered lactone with concomitant retro-aldoi fragmentation to give a 78% yield of the ester 145 (from photosubstrate 143) upon methylation with diazomethane. KOH; CH2N2

hv Mé

'0-f

144

Me

Me

78o/o

fo]

o 1

Q N ) ' ' OMe ' Me 145

An intramolecular dioxinone photocycloaddition is used in the synthesis of (+)-valeranone.49 Irradiation of dioxinone 146 gives a high yield of cycloadduct 147, which undergoes reduction followed by spontaneous retro-aldol fragmentation. The resulting diketoaldehyde intermediate 149 is cyclized to enone 150 via aldol condensation. This enone is converted to (+)valeranone in a few steps.

Chapter 5 Large-Ring Carbocycles

Me

hv ?Γθ"

H Me 146

"Me

98%

471

OH

^fo

DIBAL

.I^O^i

Me"Me^<JMe 147

148

pTSA

*50% O

valeranone

150

149

Me

The intramolecular dioxolenone photocycloaddition/fragmentation approach provides easy access to six-, seven-, eight-membered ring keto esters 153 in excellent yields with high (> 50:1) levels of regiochemical control. 50 Me, , 0

Me

Me X

«)n

0

81% 151

, 0

hv

n = 1-3

Me X

(<)n

0

pTSA, MeOH

91% 152

C0 2 Me

■

153

The intramolecular photocycloaddition of dioxenones with alkynes is also reported. 51 Tetronates52 The photocycloaddition of tetronates is analogous to that of vinylgous esters as ß-diketone equivalents (vide supra). The MEM-protected tetronate 155 is irradiated in the presence of cyclopentene, cyclohexene and cz's-cyclooctene, and the resulting adducts 156 are immediately deprotected with titanium tetrachloride to give the hydroxyl lactones 157 as mixture of diastereomers in about 50% yield. These adducts are subjected to cesium carbonate in THF under microwave irradiation to give the ring-opened oxepanediones 158 in 74-84% yield.

Name Reactions for Carbocyclic Ring Formations

472

hv

«fc.

TiCL 50%

H OMOM

154

156

155

Cs2C03 n = 1-3

74-84%

The C-4 substituted tetronates 159 also undergo intramolecular photocycloaddition to give the tricyclic adducts 160 with the heterocyclic ring directly anellated to the cyclobutane moiety. In consistency with the rule of fives, these photocycloadditions proceed exclusively to furnish the straight adducts. H hv

74%(n = 1) 71%(n = 2) 30% (n = 3)

^>7^o 159

160

5.2.6.3 Enol Esters and Silyl Enol Ethers of ß-Ketoesters As described previously, no photocycloaddition occurs between alkenes and silyl enol ethers, 129 and 132a, and enol acetates 130 and 132b (vide supra). However, this type of enol derivatives may be suitable for photoaddition with cyclic enones. For example, irradiation of 162 in the presence of enone 161 proceeds with high regioselectivity to give adducts 163 (40%) and 164 (40%) along with a dimer of enone 161.53 As expected, irradiation of 161 with an excess of either 167 or its ethyl enol ether 168 gives in less than 10% yield the desired head-to-head adducts 169. Reduction of 164 with sodium borohydride gives lactone 165, and treatment of this lactone with dilute sodium methoxide results in transesterification of the acetoxy group followed by a retro-aidol type reaction to give the fragmentation product 166.

Chapter 5 Large-Ring Carbocycles

-C02Me

AcO^^. E

O

nv

t0 2 C

161

473

Me02C OAc

Me02C OAc

ό' Η C02Et

162

163

(5 H C02Et

40%

164 40% NaBH4

98% Me02C

Me02C OAc

NaOMe

'in

77%

ο-Λ 165

166 C02Me or EtOpC 161

EtO.

<10%

Et02C

ft 168

167

Me02C OR

H C02Et

169 R = H, Et

The trimethylsilyl ether 171 also undergoes photoaddition with 2cyclopentenone to give the head-to-head cis-anti-cis adduct 172 albeit in a modest 35% yield along with a considerable amount of enone dimer 53 Reduction of 173 with sodium borohydride gives lactone 174, which, upon

o

170

JU

TMSO^/\

hv

EtO,C

35%

171

H OTMS

NaBH,

ό' Η C02Et 172

TBAF 65%

174

norasterisscanolide

H OTMS

83% 173

Name Reactions for Carbocyclic Ring Formations

474

treatment with fluoride ion, leads to the 6/7 fused ketone 174 via retro-aldol fragmentation. This compound has all the structural features of asteriscanolide, but lacks the three methyl groups. Irradiation of isophorone and a 15-fold excess of enol ether 177 results in the formation of a diastereomeric mixture of adducts 178 in quantitative yield.54 On brief treatment with tetrabutylammonium fluoride, the mixture of photoadducts 178 undergo cyclobutane ring-opening to give two epimeric diketo esters 179 in 70% yield. The Claisen condensation of these diketo esters proceeds on treatment with sodium hydride in refluxing THF, and a single enolized trione 180 is isolated in good yield. This photochemical approach provides easy access to a series of bicyclic 1,3-cyclohexanediones.

C02Et TMSO

Me

C02Et ^OTMS

177 O C02Et Me

TBAF 70%

►- M e

Me 179

180

Photocycloaddition of β,β-diethoxyacrylate 182 with cyclopent-2enone proceeds with excellent regioselectivity to give 183 as a mixture of diastereomers.55 Reduction of this mixture with sodium borohydride leads to alcohol 184, exposure of which results in fragmentation and lactonization to give lactone 185 in 59% yield from enone 181.

Chapter 5 Large-Ring Carbocycles

475 O

CO?Et

NaBU,

pTSA 59% from 181

184

5.2.7

o: 185

'C02Et

Synthetic Utility

The power of the de Mayo reaction, especially the intramolecular version, has been demonstrated in the syntheses of numerous natural products, and only a few representatives are described as below. 12-epi-Lycopodine (Wiesner, 1968)7 Wiesner carried out pioneering studies on the photocycloaddtion of vinylogous imides in the 1960s, and he first applied the intramolecular photochemical [2 + 2] enone-olefin cycloaddition reaction in natural product synthesis. In his landmark synthesis of 12-epz-lycopodine, compound 186 is irradiated to give a 70% yield of photoadduct 187. Protection of the ketone, epoxidation of the exocyclic double bond, and reduction of the epoxide give ketal alcohol 188. Deprotection of the ketal and spontaneous re/ro-aldol fragmentation lead to the diketone 190. Of note is that the bond cleaved in this retro-aldol pathway (i.e., 189 to 190) is different from that of typical de Mayo reactions. Diketone 190 transforms to the tetracyclic alcohol 191 via aldol reaction, and this alcohol is converted to 12-ep/'-lycopodine in four steps. HO(CH2)2OH, pTSA; mCPBA; LiAIH4

/ A

\ Me O

Name Reactions for Carbocyclic Ring Formations

476

NaOMe

HCI Me^ 190

189

PCI 5 ; Zn; LiAIH4; Jones oxidation Me1"

12-ep/-lycopodine

191

(±)-ß-Himachalene (de Mayo, 1969)56 Photocycloaddition of enol acetate 193 and ketal 192 proceeds with high regioselectivity to give adduci 194 in excellent yield. Reduction of the ketone and mesylation of the resulting alcohol give compound 195, which undergoes hydrolysis and spontaneous fragmentation under basic conditions to give ketone 196 in 35% yield from enol acetate 193. This ketone is converted to ß-himachalene in a few steps. OAc

AcO

hv

Me' 193

192

/V-k Cr\) \ /

O

OAc

Na0H

Me 'óMs UIVIS

195

\>

Me

NaBH4; MsCI, Et3N

O

194

·

35%

from 193 196

ß-himachalene

Chapter 5 Large-Ring Carbocycles

477

Longifolene (Oppolzer, 1978);57 Sativene (Oppolzer, 1984)58 Longifolene is a sesquiterpene isolated from a variety of plant sources, and like many other smaller terpenoids, it has found use in the perfume industry due to its rich woody odor. This compound is relatively inexpensive and has limited commercial use, but the longifolene skeleton has served as a subject for synthetic planning and strategy. This compound was first synthesized by Corey in 1961,59 and it was among the first molecules on which Corey demonstrated his new retrosynthetic analysis theory.60 A number of impressive total syntheses have been accomplished since then, including the photochemical approach by Oppolzer in 1980. Thus irradiation of the crude enol acetate 198a and 199a (derived from diketone 197) through Pyrex affords regioselectively adducts 200a as a 1:3 mixture of stereoisomers in 78% yield. As described previously, the acetylation of 1,3-diketone 107 is not regiospecific, but the two enol acetates interconvert via a photo-Fries process. However, only the enol acetate 199a participates in the cycloaddition. Hydrolytic cleavage of the acetoxy group requires heating of 200a with 4% potassium hydroxide in dioxane/water at 100 °C, and under these harsh conditions the resulting retro-aldoi product 201 undergoes further

ctr>

^Ψ

RCI, Py 80% (R = Ac) 88% (R = Cbz)

197

/7v, pyrex, C6H-|2 78% (R = Ac) 83% (R = Cbz)

I

0 200a/b /-Pr

O longifolene

vA^

\

0 199a/b

198a/b

OR

OR

CX r >; Λί \J K-, +

t

/TV

A O

H2, Pd, HOAC 80% from 200b

li

0 201

\

Name Reactions for Carbocyclic Ring Formations

478

intramolecular aldol reaction. To this end, the mixture of the crude enol carbonates 198b and 199b is irradiated to give adducts 200b as a 2:3 mixture of stereoisomers in 83% yield. Hydrogenolysis of 200b results in clean retroaldol cleavage to give the 1,5-diketone in 83% yield. The exclusive formation of the crossed adduci is typical of systems with two atoms between the two double bonds. Diketone 201 has been converted to longifolene and sativene. (±)-A8'9-Capnellene (Pattenden, 1980)61 The enol benzoate 202 undergoes regioselective and stereoselective photocycloaddition to give adduci 203 in 98% yield. Treatment of the ketobenzoate 203 with lithium hexamethyldisilazide (LHMDS), followed by methyl iodide, leads to the geminai dimethyl substituted adduci, which on fragmentation under basic conditions, gives the trimethyl substituted cyclooctane-l,5-dione 204. This dione is transformed into epiprecapnelladiene in a six-step sequence. Treatment of ep/'-precapnelladiene with boron trifluoride etherate results in a clean transannular cyclization to give A8'9-capnellene in more than 50% yield accompanied by two minor isomerie capnellenes. O

Me O

Me

6 steps

hv

202

OBz

98% 203

204

BF-,.Et,0 50% Me ep/-precapnelladiene

Δ°'-capnellene

(±)-Zizaene (Pattenden, 1981)62 Irradiation of the 6:4 mixture of enol acetates 205 and 206 produces a 7:3 mixture of the photo adducts 208 and 207. Reduction of the major photoadduct 208 followed by mesylation of the resulting alcohol leads to a mixture of isomers of the mesylate 209 in 70% yield. Treatment of the mesylate with sodium hydroxide effects simultaneous saponification and the Grab fragmentation, with the formation of a 1:2 mixture of a- and ß-methyl

Chapter 5 Large-Ring Carbocycles

479

epimers of the tricyclic alkene 210. Hydrogenation of the alkene gives the tricyclic ketone 211, accompanied by the epimer. Tricyclic ketone is a precursor to (±)-zizaene.

b °^L

OAc

'Ì Λ /

205

Me

+

0

1

L 206

OAc

u^y^Me 207 + o

hv 89% Me.

OAc

χk

Sf 0Ac

NaBH4 (79%);

MsO.H , OAc

MsCI (96%)

209

208

NaOH H2, Pd/C

zizaene

210

(±)-Pentalenene (Pattenden, 1984)'63 Irradiation of the silyl enol ether 212 results in regioselective intramolecular [2 + 2] photocycloaddition producing only the tricyclic ketone 213 in 81% yield from the ß-diketone. The silyl enol ether of the ß-diketone 212 is chosen as a photosubstrate instead of the enol ester (acetate, benzoate) because of the comparative neutrality of silyl ethers toward organometallic reagents and because of the known affinity of silicon for fluoride ion to trigger the Grob fragmentation step. Addition of the tricyclic ketone 213 with Me3CuLi2 brings about stereoselective formation of the tertiary alcohol, which undergoes the smooth Grab fragmentation upon treatment with hydrofluoric acid to give the enone 215 in 73% yield. This enone is converted to the cycloocta-l,5-diene 216 following the Witting reaction with methylenetripehylphosphorane and isomerisation of the resulting olefin with rhodium trichloride. Treatment of the cycloocta-l,5-diene 216 with boron trifluoride etherate results in stereoselective transannular cyclization, producing pentalenene in 38% yield, along with /so-pentalenene as a minor isomer.

Name Reactions for Carbocyclic Ring Formations

480

Me Me

f " f Me Me

*»' Pyrex

Me3CuLi2

OTBS

Me. Me Me, ΗΟ,,Ι

ÖTBS 213

212

Ph3P=CH2; RhCI3«3H20

HF, H20 *62% from 213

ÖTBS 214

xr J

Me

Me

A

Me

216

BR.EtoO 38% pantalenene

minor /so-pentalenene

(±)-Hirsutene (Weedon, 1985)64 Photocycloaddition of 5,5-dimethylcyclohexane-l,3-dione to 2-methyl-2cyclopentenol followed by in situ silylation of the crude photoadducts, 219a and 220a, with fért-butyldimethylsilyl chloride to give an 89% yield of the 1:1 mixture of the isomerie silylated, hydroxyl-substituted cyclooctane-1,5diones 219b and 220b. The protection of the hydroxyl group in the photoadducts 219a and 220a proves necessary due to their instability. Treatment of the mixture of silyl ethers with a low-valence titanium reagent (McMurry coupling reaction) results in intramolecular reductive coupling of the dione function to give the hirsutene carbon skeleton 221 with the desired regiochemistry in 17% yield. Desilylation with fluoride ion, followed by sequential catalytic hydrogenation and the Jones oxidation, completes the formal synthesis of hirsutene. This route suffers from poor regioselectivity in the photocycloaddition step, typical of the intermolecular de Mayo reaction.

481

Chapter 5 Large-Ring Carbocycles Me le Me

.<

17 217

71

>

II

Me'

218

ηυ; TBSCI, Imidazole

89% a:R = H b: R = TBS

219a/b

OH

TiCI3, K

17% H

MeMe "e

H Me\ hirsutene

Mei OTBS

221

222

Taxane Skeleton (Inouye, 1985;65 Winkler, 198966) A system analogous to the taxanes has been prepared by using the intramolecular de Mayo reaction of vinylogous esters. Irradiation of the mixture of diastereomers 223 results in cycloaddition of one diastereomer to give adduct 225 and recovery of the other isomer 224. The tetrahydrofuran is oxidized with R.UO4 to the lactone, which is saponified with concomitant cyclobutane cleavage to the diketo acid 227.

^5

ηυ 30-40%

Me

H 225

223

| RuCI4 Me

R0 2 C

KOH 80%

227

C02H

^5 ÖH

226

482

Name Reactions for Carbocyclic Ring Formations

Photocycloaddition of dioxinone 228, with the correct C-l/C-3 relative stereochemical relationship for taxane construction, leads to the formation of a single diastereomer 229. Fragmentation under basic conditions and treatment of the resulting keto acid with diazomethane generates the keto ester 230 and its C-15 epimer (3:1 ratio) in quantitative yield.

OMe KOH, MeOH; CH2N2 R = C02Me

Vindorosine (Winkler, 1990)'67 Irradiation of 231 gives, after the reiro-Mannich fragmentation of the photoadduct 232, a 91% yield of 233. The single stereogenic center in the photosubstrate leads to complete stereochemical control in the formation of the cyclobutane intermediate 232, which contains two new strereogenic centers. Treatment of 233 with lithium diisopropylamide, followed by an excess of féri-butyldimethylsilyl trillate and reaction of the crude product with tetrabutylammonium fluoride, results in the formation of the desired tetracyclic product 234 in 51% yield. This compound is converted to tetracyclic ketone 235, which is an advanced intermediate in Büchi's synthesis of vindorosine.

91%

CBZ 232

233

CBZ

483

Chapter 5 Large-Ring Carbocycles

LDA, TBNMSOTf; TBAF » 51%

5 steps

CBZ 234

235

vindorosine

Manzamine A (Winkler, 1998)'68 Manzamine A contains an unprecedented pentacyclic core consisting of 13and 8-membered rings attached to a central pyrrolo[2,3-/]isoquinoline system and an array of five stereocenters. It would require the identification of a novel synthetic strategy bolstered by a supply of synthetic transformations to conquer such a complex molecule. To this end, an elegant photochemical approach to manzamine A has been developed by Winkler. Thus photoaddition and retro-Mannich fragmentation of the tertiary vinylogous amide 236 leads, via O-closure of the ketoiminium intermediate 238, to aminal 239. The isomerisation of 239 to the manzamine tetracycle 241 proceeds upon exposure to pyridinium acetate to give 241 in 20% overall yield from photosubstrate 236 (an average of 60% yield/step for photoaddition, fragmentation, and Mannich closure). As expected, 241 is produced as a single stereoisomer, presumably because of the overwhelming influence of the lone C-34 stereocenter in 236 controlling the formation of the resulting stereogenic centers during the cascade sequence. Of note is that the C-12 stereochemistry is not assigned at this stage of the synthesis and thus not defined in the scheme, but a single stereochemical arrangement occurs at this site. In fact, the stereochemistry at C-12 does not matter for the synthesis since it would be destroyed during subsequent transformations to install the functional requirements of manzamine A. This tetracyclic compound is converted to manzamine A in a 12-step sequence.

484

Name Reactions for Carbocyclic Ring Formations

* 41

manzamine A

(±)-Saudin (Winkler, 1999)69 Irradiation of 242 leads to the formation of 243 as a single diastereomer in 80%) yield. Treatment of 243 with «-BuLi and Tf2Ü in the presence of TMEDA gives the enol triflate, which undergoes Stille coupling with 3furyltributylstannane to give the furyl enol ether 244 in 95%> yield. Exposure of 244 to lithium hydroxide and cyclization of the resulting hemiketal ketoacid 245 furnishes (±)-saudin in 52%> yield.

485

Chapter 5 Large-Ring Carbocycles M e

\ / 0 ^ ^Ο Μβ-η ( X ^— Me

n-BuLi, TMEDA, Tf 2 0, 81%;

Me-ήΤ Τ Μ Θ Ο^ A ^Η

Stille coupling with (3-furyl)SnBu3

·

M e

y O v O Me-η Tivie

PPTS 52% from 244

244

245

(±)-Ingenol (Winkler, 2002)70 Photocycloaddition of the allylic chloride 246 proceeds in 60% yield to give the desired photoadduct 247. Fragmentation of 247 with methanolic potassium carbonate generates ester 248. Reduction of the ester with lithium aluminium hydride, elimination of the chloride with DBU, and silylation of the primiary alcohol withfert-butyldimethylsilylchloride (TBSC1), give 249 as a 7:1 mixture of the C-6 cc:ß epimers in 35% yield from 247. Ingenol is derived from 247 in a 24-step sequence.

Name Reactions for Carbocyclic Ring Formations

486

"CI ,

Me..,/

Me MMp e

0_^

i °

hv

Me-,

60%

KOH,

Me

Me

MeOH

ΓΜβ O

'

'<,/cTV.CI

■

<

& CO,Me

H 246

248 H

LiAIH4; DBU; TBSCI

24 steps

'—OTBS 249

/—k^/Me

Me^^V H0

35% from 247

5.2.8

Me-,

Me

oy,„H

^io>

\*H

HO ^ O H ingenol

Experimental

(10£40a/?)-10<2-Oxopropyl)-2^1040a-tetrahydropyrrolo[l,2b\ isoquinoline-1,5-dione22 A solution of 6-(l-oxoisoquinolin-2(l//)-yl)hexane-2,4-dione (101 mg, 0.39 mmol) in acetonitrile (10 mL) was purged with nitrogen for 15 min. The reaction mixture was irradiated through a Pyrex filter at room temperature for 1.5 h, and then evaporated in vacuo. The residue was purified by silica gel flash chromatography eluting with 2:1 ethyl acetate/hexane to give the title compound as a white crystalline solid (72 mg, 72% yield). 5.2.9

References

1. 2. 3. 4. 5. 6.

Ciamician, G.; Silber, P. Ber. 1902, 35, 4129. Stobbe, H. Ber. 1912, 45, 3396. Ciamician, G.; Silber, P. Ber. 1908, 41, 1928. Buchi, G.; Goldman, I. M. J. Am. Chem. Soc. 1957, 79,4741. Cookson, R. C; Crundwell, E.; Hudec, J. Chem. Ind. 1958, 1003. Eaton, P. E.; Cole, T. W. Jr. J. J. Am. Chem. Soc. 1964, 86, 962; and J. Am. Chem. Soc. 1964, 55,3157. Wiesner, K.; Musil, Wiesner, K. J. Tetrahedron Lett. 1968, 5643. Eaton, P. E. J. Am. Chem. Soc. 1962, 84, 2454. Corey, E. J.; Bass, J. D.; Lemahieu, R.; Mitra, R. B. J. Am. Chem. Soc. 1964, So, 5570. (a) Corey, E. J.; Mitra, R. B.; Uda, H. J. Am. Chem. Soc. 1963, 85, 362. (b) Corey, E. J.; Mitra, R. B.; Uda, H. J. Am. Chem. Soc. 1964, 86, 485. (c) Corey, Nozoe, S. J. Am. Chem. Soc. 1964, 86, 1652. (d) Corey, Nozoe, S. J. Am. Chem. Soc. 1965, 87, 5733.

9. 10.

Chapter 5 Large-Ring Carbocycles 11. 12. 13.

14. 15. 16. 17. 18. 19. 20. 21. 22. 23. 24. 25. 26. 27. 28. 29. 30. 31. 32. 33. 34. 35. 36. 37. 38. 39. 40. 41. 42. 43. 44. 45. 46. 47. 48. 49. 50.

487

[R] Corey, E. J.; Cheng, X. -M. The Logic of Chemical Synthesis, Wiley, New York, 1989, pp. 153-155. de Mayo, P.; Takeshita, H.; Sattar, A. M. B. A. Proc. Chem. Soc. London, 1962, 119; de Mayo, P.; Takeshita, H. Can. J. Chem. 1963, 41, 440 [R] For reviews on enone-olefm cycloadditions including de Mayo reactions, see: (a) Eaton, P. E. Ace. Chem. Res. 1968, 1, 50. (b) de Mayo, P. Aec. Chem. Res. 1971, 4, 41. (c) Oppolzer, W. Pure Appi. Chem. 1981, 53, 1181. (d) Oppolzer, W. Ace. Chem. Res. 1982,15, 135. (e) Schuster, D. I.; Lem, G.; Kaprimidis, N. A. Chem. Rev. 1993, 93, 3. (f) Schuster, D. I.; Lem, G.; Kaprimidis, N. A. Chem. Rev. 1993, 93, 3. (g) Crimmins, M. T. Chem. Rev. 1988, 88, 1453. (h) Winkler, J. D.; Bowen, C. M.; Liotta, F. Chem. Rev. 1995, 95, 2003. [R] Nicolaou, K. C; Snyder, S. A. Classics in Total Synthesis II, Wiley-VCH, 2003, pp. 211-236. www.uwo.ca/sci/publications/history/deMayo.html. (a) Loutfy, R. O.; de Mayo, P. J. Am. Chem. Soc. 1977, 99, 3559; Froese, R. D.; Lange, G. L.; Goddard, J. D. J. Org. Chem. 1996, 61, 952. Lange, G. L.; Organ, M. G.; Lee, M. Tetrahedron Lett. 1990, 31, 4689. Quevillon, T. M.; Weedon, A. C. Tetrahedron Lett. 1996, 37, 3939. (a) Srinivasan, R.; Carlough, K. H. J. Am. Chem. Soc. 1967, 89, 4932; (b) Liu, R. S. H.; Hammond, G. S. J. Am. Chem. Soc. 1967, 89, 4930. Beckwith, A. L. Tetrahedron 1981, 37, 3063. Bajgrowicz, J. A.; Petrzilka, M. Tetrahedron 1994, 50, 7461. Minter, D. E.; Winslow, C. D. J. Org. Chem. 2004, 69, 1603. Oppolzer, W.; Bird, T. G. C. Helv. Chim. Ada. 1979, 62, 1199. Bagley, M. J.; Mellor, M.; Pattenden, G. J. Chem. Soc, Chem. Commun. 1979, 235. Bagley, M. J.; Mellor, M.; Pattenden, G. J. Chem. Soc, Perkin Trans. 11983, 1905. Seto, H.; Hirokawa, S.; Fujimoto, Y.; Tatsuno, T. Chem. Lett. 1983, 989. Seto, H.; Fujimoto, Y.; Tatsuno, T.; Yoshika, H. Synth. Commun. 1985,15, 1217. Seto, H.; Tsunoda, S.; Ikeda, H.; Fujimoto, Y.; Tatsuno, T.; Yoshika, H. Chem. Pharm. Bull. 1985, 33, 2594. Kaczmarek, R.; Blechen, S. Tetrahedron Lett. 1986, 27, 2845. Tamura, Y.; Kata, Y.; Ishibashi, H.; Ikeda, M. J. Chem. Soc, Chem. Commun. 1971, 1167. Tamura, Y.; Y.; Kata, Y.; Ishibashi, H.; Ikeda, M. Tetrahedron Lett. 1972, 1977. Tamura, Y.; Ishibashi, H.; Ikeda, M. J. Org. Chem. 1976, 41, 1277. Ikeda, M.; Ohno, K.; Homma, K.; Ishibashi, H.; Tamura, Y. Chem. Pharm. Bull. 1981, 29, 2062. Kojima, T.; Inouye, Y.; Kakisawa, H. Bull. Chem. Soc. Jpn. 1985, 58, 1738. Pirrung, M. C; Webste, N. J. G. J. Org. Chem. 1987, 52, 3603. Winkler, J. D.; Ragains, J. R. Org. Lett. 2006, 8, 4031. For pioneering studies on the photocycloaddtion of vinylogous imides, see (a) Böhme, E. H.; Valenta, Z.; Wiesner, K. Tetrahedron Lett. 1965, 2441. (b) Wiesner, K.; Jirkovsky, I.; Fishman, M.; Williams, C. A. Tetrahedron Lett. 1967, 1523. Tamura, Y.; Y.; Kata, Y.; Ishibashi, H.; Ikeda, M. Tetrahedron Lett. 1972, 1977. Schell, F. M.; Cook, P. M. J. Org. Chem. 1984, 49, 4067. Vogler, Β,; Bayer, R.; Meiler, M.; Kraus, W. J. Org. Chem. 1989, 54,4165. Amougay, A.; Pete, J.-P.; Piva, O. Tetrahedron Lett. 1992, 33, TÌA1. Winkler, J. D.; Müller, C. L.; Scott, R. D.. J. Am. Chem. Soc. 1998,110, 4831. Ragains, J. R.; Winkler, J. D. Org. Lett. 2006, 5,4437. (a) Kwak, Y.; Winkler, J. D. J. Am. Chem. Soc. 2001, 123, 7429. (b) Winkler, J. D.; Fitzgerald, M. E. Synlett 2009, 562. Baldwin, S. W.; Wilkinson, J. M. J. Am. Chem. Soc. 1980,102, 3634. Sato, M.; Sekiguchi, K.; Kaneko, C. Chem. Lett. 1985, 1057. Sato, M.; Takayama, K. Abe, Y.; Furuya, T.; Inukai, N.; Kaneko, C. Chem. Pharm. Bull. 1990, 38, 336. Blaauw, R. H.; Briere, J.; Jong, R. de; Benningshof, J. C. C; Ginkel, A. E. van; Fraanje, J.; Goubitz, K.; Schenk, H.; Rutjes, F. P. J. T.; Hiemstra, H. J. Org. Chem. 2001, 66, 233. Takeshita, H.; Cui, Y.; Kato, N.; Mori, A. Bull. Chem. Soc. Jpn. 1993, 66, 2694. Winkler, J. D.; Hey, J. P.; Hannon, F. J. Heterocycles 1987, 25, 55.

488 51. 52. 53. 54. 55. 56. 57. 58. 59. 60. 61. (a) (a) (a) 62. 63. 64. 65. (a) 66.

Name Reactions for Carbocyclic Ring Formations Winkler, J. D.; McLaughlin, E. Org. Lett. 2005, 7, 227. Kemmler, ML; Herdweck, E.; Bach, T. Eur. J. Org. Chem. 2004, 4582. Lange, G. L.; Organ, M. G. J. Org. Chem. 1996, 61, 5358. Liu, H.; Dieck-Abularach, T. Tetrahedron Lett. 1982, 23, 295. Audenhove, M. V.; Termont, D.; Keukeleire, D. D.; Vandewalle, M.; Claeys, M. Tetrahedron Lett. 1978, 31,2057. Challand, B. D.; Kornis, H.; Lange, K. G.; de Mayo, P. J. Org. Chem. 1969,34, 794. Oppolzer, W.; Godei, T. J. Am. Chem. Soc. 1978,100, 2583. Oppolzer, W.; Godei, T. Helv. Chim. Ada. 1984, 67, 1154. Corey, E. J.; Ohno, M.; Vatakencherry, P. A.; Mitra, R. B.J. Am. Chem. Soc. 1961, 83, 1251. [R] Nicolaou, K. C.; Montagnon. Molecules That Changed the World, Wiley-VCH, 2007, pp. 107-112. (a) Birch, A. M.; Pattenden, G. J. Chem. Soc., Chem. Commun. 1980, 1195. (b) J. Chem. Soc. Perkin Trans. 11983, 1913. Parker, A. J.; Pattensen, G. Tetrahedron Lett. 1981, 22, 2599. (b) Parker, A. J.; Pattensen, G. J. Chem. Soc, Perkin Trans. 11983, 1901. Pattenden, G.; Teague, S. J. Tetrahedron Lett. 1984, 25, 3021. (b) Pattenden, G.; Teague, S. J. Tetrahedron 1987, 43, 5637. Disanayaka, B. W.; Weedon, A. C. J. Chem. Soc, Chem. Commun. 1985, 1282; (b) Disanayaka, B. W.; Weedon, A. C. J. Org. Chem. 1987, 52, 2905; Kojima, T.; Inouye, Y.; Kakisawa, H. Chem. Lett. 1985, 323. Winkler, J. D.; Lee, C.; Rubo, L.; Müller, C. L. J. Org. Chem. 1989,54, 4491. Winkler, J. D.; Scott, R. D.; Williard, P. G. J. Am. Chem. Soc. 1990, 112, 8971. (a) Winkler, J. D.; Axten, J. M. J. Am. Chem. Soc. 1998, 120, 6425. (b) Winkler, J. D.; Axten, A.; Hammach, A. H.; Kwak, Y.; Lengweiler, U.; Lucerò, M. J.; Houk, K. N. Tetrahedron 1998, 54, 7045. Winkler, J. D.; Doherty, E. M. J. Am. Chem. Soc. 1999, 121, 7425. (b) Winkler, J. D.; Doherty, E. M. Tetrahedron Lett. 1998, 39, 2253. Winkler, J. D.; Rouse, M. B.; Greaney, M. F.; Harrison, S. J.; Jeon, Y. T. J. Am. Chem. Soc. 2002,124, 9726.

Chapter 5 Large-Ring Carbocycles

5.3

489

Ring-closing Metathesis

Nicole L. Snyder and Kevin W. Graepel 5.5.7 Description

Catalysts:

(FaCkHaCCO/-,.^ (FaCkHgCCc/

N

Ph

PCy3 Cl/,„i Ru CI I PCy3

Ph Ph

JRu=v N Cl^l Ph PCy3

1 N

Mes" y ^Mes CI/, I %*Ph U=Sv

CI*' I H PCy3

l=\ N Mes Y ^ M e s CI/, I %*Ph N

Cl

,U 3 PCy

H

Mes—Ν^,Ν—Mes

CI/,T

Ru^.

6

Ring-closing or olefin metathesis is the intramolecular redistribution of alkylidene moieties between two alkenes in the presence of a catalytic amount of a metal carbene to provide for a new product olefin and a byproduct olefin that is usually volatile in nature. 5.3.2 Historical Perspective Ring-closing metathesis reactions were first used in 1980 by Tsuji1 and Villemin.2 However, it was not until the early 1990s that well-defined, single-component catalytic systems were developed independently in the research laboratories of Richard R. Schrock3 and Robert H. Grubbs.4 In 2005, Schrock and Grubbs shared the Nobel Prize in chemistry with Yves Chauvin for their work in this area. Schrock's molybdenum catalyst (1), Grubbs first- and second-generation catalysts (2-5), and the GrubbsHoyveda catalyst (6) are the most common catalysts used in ring-closing metathesis today.

490

Name Reactions for Carbocyclic Ring Formations

Over the past 20 years ring-closing metathesis has become a powerful tool for the synthesis of a wide range of carbocyclic compounds. Carbocycles containing as few as 5 and as large as 18 carbon atoms have been prepared. Traditionally, five-, six-, and seven-membered ring carbocycles have been the most common targets for ring-closing metathesis. Recent developments in catalyst design, and a better understanding of substrate and reaction condition requirements for ring-closing metathesis have led to the increased use of this reaction in the synthesis of large carbocycles and macrocycles. 5.3.3 Mechanism

H2C=CH2

The mechanism for ring-closing metathesis using ruthenium complexes 3 and 4 has been well established both experimentally5 and theoretically.6 Entry into the catalytic cycle begins with the initial dissociation of the phosphine ligand to form the active 14-electron metalacarbene complex (A). This complex then coordinates with the an α,ω-diene (B) to form a 16-electron system. Migratory insertion, presumably via a [2 + 2] cycloaddition, gives rise to the corresponding metallacyclobutane intermediate (C), which has been characterized by NMR spectroscopy.7 Metallacyclobutane (C) then undergoes a retro-[2 + 2] cycloaddtion to form a new 16-electron carbene intermediate (D) with the concomitant release of an alkene, usually ethylene. Intermediate D then undergoes an intramolecular [2 + 2] cycloaddition reaction to form a new metallocyclobutane E, which subsequently undergoes

Chapter 5 Large-Ring Carbocycles

491

a retro-[2 + 2] cycloaddition to produce the desired cyclic olefin (F), while regenerating the active 14-electron metallacarbene complex A. The reaction is entropically driven and there is still some debate as to the rate-limiting step of the reaction. Schrock's catalyst 1, a molybdenum imido complex, has been shown to be highly active; however, its sensitivity to oxygen, moisture, and some polar functional groups has limited the utility of this catalyst in the synthesis of complex and highly functionalized compounds. On the other hand, Grubbs's first- and second-generation ruthenium carbene catalysts 2-5 and the Grubbs-Hoyveda catalyst 6 are less sensitive to oxygen and moisture. In addition, the functional group tolerance exhibited by 2-6 has made them the catalysts of choice in the synthesis of many complex synthetic targets.8 Despite the sensitivity and functional group tolerance of catalysts 2-6, Schrock's catalyst 1 is still the best catalyst in many cases for forming rings with high steric and electronic demands. In general, ring-closing is fastest for smaller rings (5-7-membered rings) for which enthalpic and entropie factors are favorable.9 The formation of eight-, nine-, and ten-membered rings are particularly problematic due to conformational constraints. Conformationally directed ring-closing metathesis using cyclic precursors has been widely used to overcome many of the problems associated with the synthesis of larger rings.10 gem-Dialkyl11 and Thorpe-Ingold effects12 have also been exploited in an effort to produce larger rings via ring-closing metathesis. In addition, Hoye and co-workers recently demonstrated that substrates containing allylic alcohols are activated towards ring-closing metathesis, suggesting that the installation of such groups might be useful when employing ring-closing metathesis for the synthesis of larger rings.13 The reaction conditions for ring-closing metathesis have also been studied.14 In general, low concentrations (0.1 M-0.1 inM) of catalyst favor ring formation, while higher catalyst concentrations favor cross-metathesis and polymerization reactions. Ring-closing metathesis reactions have also been shown to strongly depend on the solvent and temperature of the reaction. Experimental evidence has shown that polar solvents lead to higher initiation rates, as they are able to better stabilize the active 14-electron metalacarbene complex.15 A quick survey of the literature reveals the polar solvent dichloromethane is one of the most frequently used solvents for ringclosing metathesis, supporting this observation. Benzene and toluene are also commonly employed, as catalyst degradation tends to be slower with these solvents. It is interesting that a recent study by Adjiman, Taylor, and co-workers suggests that cyclohexane and acetic acid may, in fact, be the best solvents for ring-closing metathesis.16 Finally, the use of higher temperatures over long reaction periods has been shown to lead to catalyst degradation.

Name Reactions for Carbocyclic Ring Formations

492

5.3.4 Variations and Improvements The most notable improvements for ring-closing metathesis have been in the development of new catalysts.17 In particular, the "phosphine mimic's" 4-6, as well as several variants of these complexes have proven to be more reactive with electronically deactivated and sterically hindered alkenes, both of which have presented significant challenges for ring-closing metathesis. For example, the Blechert catalyst 718 and Grela catalyst 819 have found application in the ring-closing metathesis of substrates that showed little or no reactivity when catalyzed with 1-6. Grubbs-Hoyveda derivative 9 has also recently been employed in the synthesis of tetra substituted olefins. Mes—N

^N—Mes

CI/, I Ru=\

Mes—N

90

X N—Mes

CI/. Ru=\ CP

aR u = \

'Qj

''Q3-N* 8

9

In addition to sterics, a major limitation with the ruthenium-based catalysts has been the formation of stable Fischer carbenes, which tend to be electronically deactivated toward metathesis. Previously, most groups were able to circumvent this issue by building sterics into olefins prone to Fischer carbene formation, thus driving the reaction forward by forcing the catalyst to coordinate with the less reactive alkene. The advent of new catalysts, such as the commercially available second generation catalysts 4-5 and the Grubbs-Hoyveda catalyst 6, as well as catalysts 7-9 has opened new opportunities in this area. For systems that remain problematic, relay ringclosing metathesis has proven useful in directing catalyst coordination. ' The development of several water-soluble catalysts, including several 99

9^

derivatives of the Grubbs's first-generation (10a,b, 11 ), and secondgeneration (1224) and the Grubbs-Hoyveda catalysts (13a,25b,26c27) have expanded the scope of these catalysts to substrates that require more polar reactions conditions. These catalysts have also found wide applications in green chemistry processes28 and for olefin metathesis in chemical biology.29 The recent development of ruthenium olefin metathesis catalysts bearing carbohydrate ligands (14-15) is also of promise in this area.30

Chapter 5 Large-Ring Carbocycles

CI/, I ,*Ph Cl^| ^ H Cl„ I

Y3

493

R-N

e«

-P(CH3)3

N-Mes

c,-?u^Ph PCy3

rn

R = CONH(CH2)2OPEG-CH3 10a,R=-f-^^X

12

10b, R = 13a, R1 = CH2OPEG-CH R2,R3 = H 13b, R1 = CH2NH3+Cr R2 = CH2N(CH3)3+Cr R3 = H 13c, R \ R 2 = H R3 = NEt2CH3+r

/OAc

AcO^^°x

AcO-\^V^N

Ac0

f=\

aJ

?^OAc

N-Mes

PCy3 ™

14

^^°s

AcO-V^\^

Ac0

N

f=\

v/

a,

N _ M e s

PCy3 P

15

Two additional limitations with ruthenium-based catalysis are catalyst lifetime and the efficient removal (and subsequent recovery) of residual catalyst and decomposition products from the desired reaction products.31 Currently, only the Grubbs-Hoyveda catalyst 6 can be readily recovered by flash chromatography. Numerous special workup and purification methods have been developed to solve the later problem.32 However, the recent immobilization of ring-closing metathesis catalysts via the N-heterocyclic carbene to a solid support is gaining increasing attention as solution to both of these problems. In most cases, these immobilized catalysts provide both greater efficiency and easy recovery.33 A recent report by Grubbs and co-

494

Name Reactions for Carbocyclic Ring Formations

workers on a well-defined silica-supported olefin metathesis catalyst for catalysis offers new promise in this area. 5.3.5 Synthetic Utility General Utility In 1993, Grubbs and co-workers reported the first examples of ring-closing metathesis using l 35 and 236 to prepare carbocyclic compounds. Reaction of 16 with 2-4 mol % of either 1 or 2 in benzene at room temperature furnished the correspondingfive-memberedring carbocycle in 91% (using 1) and 85% (using 2). OTBS 16

1,PhH, rt, 15-30min.,91%

9TBS

or 2, PhH rt, 5 h, 85%

Since their initial report, this methodology has been extended to the formation of six-, seven-, eight- and larger ring carbocyclic systems. The following sections highlight significant application of the ring-closing metathesis strategy in the synthesis of these systems. Five-Membered Rings Shibasaki and co-workers used a ring-closing metathesis approach to prepare a number of five-, six-, and seven-membered rings from electron-deficient olefins.37 Treatment of acyclic enol ether 18 with 7 mol % of 3 in refluxing benzene provided the corresponding cyclic enol ether 19 in 94% yield. Deprotection of the silyl ether 19 (not shown) resulted in the corresponding cyclic ketone, a valuable synthetic intermediate in natural products synthesis and a number of industrial processes. The authors reported additional examples of the synthesis of five-membered ring carbocycles as part of this study. R

R ?TMS

R=C02Et 18

OTMS Y

3

PhH

reflux, 1 h 94%

"

R-j—/ R

19

Independently, Aggarawa and co-workers prepared five-, six-, and seven-membered carbocyclic methyl and silyl enol ethers bearing phenyl and

Chapter 5 Large-Ring Carbocycles

495

cyclohexyl substituents.38 Dienes 20 and 22 required upward of 20 mol % of 4 in refluxing benzene to achieve the desired products 21 and 23 in 60 and 65% yeild, respectively. The authors attributed the modest yields to a lack of gem-diester substituents, a pattern, which has been known to dramatically increase the rates of cyclization.39 R

OTBDMS

20, R = Ph 22, R = Cy

TBDMSO-^Y^X^R

4

*

PhH reflux

V

/

21,R = Ph 60% 23, R = Cy 65%

Roush and co-workers used olefin metathesis as a key step in their enantioselective and diastereoselective preparation of several cyclic ßhydroxy allylsilanes.40 Reaction of ß-hydroxy allylsilane 24 with 10 mol % of 4 in toluene gave the corresponding carbocycle 25 in 73% yield. The authors also applied this strategy to the formation of six-membered ring carbocycles bearing cyclic ß-hydroxy allylsilanes. SiMe2Ph

OH

4 PhCH

SiMe2Ph

—-

<S-\J

3

80 °C, 2 h 73%

24

rt0H

25

6,6-Bicyclic malonamides are important intermediates in the synthesis of natural products and have recently gained attention as potential donor atoms for ligand-metal complexes. Hutchinson and co-workers employed ring-closing metathesis as a key step in the synthesis of several malonamides.41 Treatment of diethyl malonate diene 26 with a catalytic amount of 3 in dichloromethane provided the corresponding carbocycle 27 in quantitative yeild in a half an hour.

EtCr V

26

"OEt

EtO CH2CI2 rt, 0.5 h 99%

V^

OEt

27

Weinreb and co-workers reported one of the first examples of a ringclosing metathesis strategy employing vinyl chlorides.42 Vinyl chloride 28, when reacted in the presence of 10 mol % of 4 in refluxing benzene,

Name Reactions for Carbocyclic Ring Formations

496

provided the corresponding carbocyclic derivative 29 in near quantitative yield. Unfortunately, reactions with the analogous vinyl bromides under similar reaction conditions gave none of the desired carbocylic products. The authors speculated that this was due to the formation of a stable, unreactive Fischer-type carbene.

„., Vc,

PhH reflux 96%

R

29

A number of research groups have used ring-closing metathesis to prepare conformationally constrained a- and ß-amino acids. The corresponding peptides that incorporate these unusual amino acid residues often exhibit interesting biological properties. Several examples of constrained amino acid residues incorporating five-membered ring carbocycles are illustrated below. Kotha and co-workers used a ring-closing metathesis strategy in their synthesis of α,α-dialkylated amino acids for the preparation of novel conformationally constrained peptide therapeutics.43 Treatment of diene precursors bearing different amino acid substitutions with 10 mol % of 3 in refluxing toluene, provided the corresponding α,α-amino acid derivatives in yields ranging from 49-90%. Undheim and co-workers employed a similar ring-closing metathesis strategy in their synthesis of α,α-dialkylated constrained amino acids,44 and Pie and co-workers also used olefin metathesis to prepare several constrained examples of α-alkoxy and a-amino esters (not shown).45 NHBoc R 30, 32, 34, 36, 38, 40,

R= R= R= R= R= R=

NHBoc PhCH 3 reflux

CONH(L)PheOCH 3 CONH(L)ValOCH 3 CONH(L)Ala(L)LeuOCH 3 CONH(L)Leu(L)AlaOCH 3 CONH(D)Val(L)ValOCH 3 CONH(D)Val(L)LeuOCH 3

31, R = 33, R = 35, R = 37, R = 39, R = 41, R =

U^/

X

R

CONH(L)PheOCH 3 75% CONH(L)ValOCH 3 90% CONH(L)Ala(L)LeuOCH 3 CONH(L)Leu(L)AlaOCH 3 CONH(D)Val(L)ValOCH 3 CONH(D)Val(L)LeuOCH 3

50% 49% 53% 75%

Abell and co-workers used ring-closing metathesis to synthesize a number of five-, six-, and seven-membered ring ß-amino acids for incorporation into ß-peptide mimetics.46 ß-Peptide mimetics have been shown to selectively disrupt bacterial cell membranes over mammalian cell

Chapter 5 Large-Ring Carbocycles

497

membranes, and as such are key targets for the synthesis of new antibiotics. Treatment of dienes 42 and 44 with a 5 mol % of 4 in benzene furnished the corresponding ß-amino acid derivatives 43 and 45 in 92 and 93% yield, respectively. Attempts to increase yields by refluxing in toluene led to a reduction in the amount of product produced, presumably due to catalyst decomposition.

CbzHN

CO3CH3

PhH rt

CbzHN

43, R: H 92% 45, R CH 3 93%

42, R = H 44, R = CH 3

Davies and co-workers also applied a ring-closing metathesis strategy in their preparation of constrained ß-amino acid derivatives.47 Their work employed a chiral auxiliary, ^(l-phenyl-ethyty-carbamic acid benzyl ester, to achieve the desired ß-amino acid derivatives in a stereoselective fashion. Treatment of diene precursors 46 and 48 with 4 mol % of 3 in refluxing dichloromethane provided the corresponding carbocyclic ß-amino acid derivatives 47 and 49 in 85 and 35% yield, respectively, with greater than 95% diastereoselectivity in both cases. The diminished yield in the case of 49 is presumably due to sterics effects. O

Ph"

^N

Λ OBn

C0 2 ißu

Phi CH2CI2 reflux, 12 h 85%, > 95% de

N

OBn

/^y*C02tBu 47

46 Ph

Ph'

Ph

J

C0 2 iBu

Ph'

N

)

CH2CI2 reflux, 12 h 35%, > 95% de

C0 2 fBu 49

Carbasugars are structurally similar to natural sugars except that a carbon atom replaces the oxygen atom in the ring. A number of five-

498

Name Reactions for Carbocyclic Ring Formations

membered ring carbacycles have been synthesized to date, most of these mimicking the reverse transcriptase inhibitor carbanucleoside (-)-carbovir. The advantage of carbaucleosides over other nucleosides (such as AZT) is that they are more resistant to phosphorylation and subsequent degradation. A number of reviews have been published highlighting advancements in the synthesis of carbanucleosides using ring-closing metathesis.48 As such, only some of the more recent and synthetically challenging syntheses of these compounds are reported here. In an effort to prepare new anti-HIV compounds with low cytotoxicity, Park and co-workers synthesized L-7V-MCd4T, a carbocyclic nucleoside containing a fused cyclopropane functionality.49 Reaction of cyclopropyl dienes 50 and 52 as a mixture of diastereomers with a catalytic amount of 4 in dichloromethane furnished the corresponding fused carbacycles 51 and 53 in 85% and 84% yield, respectively. Compound 53 was readily converted to the desired nucleoside analog in three steps.

OTBDPS

CH2CI2 rt, 1.5 h

OTBDPS

51,(2S):R 1 =OH, R2 = H 85% 53, (2R): R1 = H, R2 = OH 84%

50, (2S): R1 = OH, R2 = H 52, (2R): R1 = H, R2 = OH

L-/V-MCd4T

TBDMSO

CH2C12

TBDMSO

reflux R

iti

N

TBDMSO

55a 4 1 % 57ß 42% R = OH NH2 R= É-NH

4'-cyclopropylated carbovir analogs

In a separate study, Liu and co-workers synthesized a nucleoside incorporating a cyclopropyl group at the 4'-position.50 Reaction of

Chapter 5 Large-Ring Carbocycles

499

cyclopropyl dienes 54 and 56 with 3 mol % of 4 in refluxing dichloromethane gave a mixture of the corresponding carbasides 55 and 57 in 41 and 42% yeild, respectively. Three additional steps were required to convert compound 57 to the desired nucleoside analog. Recently, Li and co-workers reported on the synthesis of a 4'branched exomethylene carbocyclic nucleoside analog as potential mimic of olefinic carbocyclic nucleosides.51 Treatment of acyclic triene 58 with 10 mol % of 4 in refluxing dichloromethane gave the corresponding carbocycle in 74% yield. It is surprising that isomerisation of the exocyclic double bond, which has been known to occur ruthenium-based metathesis catalysts, did not occur under the reaction conditions reported. Carbocycle 59 was then readily converted to the corresponding exomethylene carbocyclic nucleoside analog in just a few additional steps.

TBDMSO TBDMSO

CH2CI2 reflux 74%

58

T B D M S O ^7~ ~ > ^ TBDMSONH2

59

N HO HO

NH, exomethylene carbocyclic nucleoside analog

Terpenes are a class of compounds composed of one or more isoprene units. Nearly all organisms produce terpenes, and many of these compounds have interesting biological activities. Many terpenes also exhibit complex architectures that pose a significant challenge for synthetic organic chemists. For these reasons, a number of scientists have set out to synthesize terpenes and terpenoid derivatives, and many recent attempts have employed a ringclosing metathesis strategy. Srikrishna and co-workers used ring-closing metathesis to synthesize HM-3 and HM-4, two aromatic sesquiterpenes with antioxidant and antibiotic activity.53 Treatment of a diastereomeric mixture of allyl alcohols 60 and 62 with 5 mol % of 3 in dichloromethane, followed by oxidation with PCC gave the corresponding enones 61 and 63 in 93 and 96% yield, respectively. These compounds were readily converted to the corresponding aromatic sesquiterpenes in just a few additional steps. Srikrishna and coworkers applied a similar strategy to the construction of the five-membered

Name Reactions for Carbocyclic Ring Formations

500

ring moieties of (±)-12-methoxyherbertenediol dimethyl ether,54 (±) laurokamurene B,55 and (±)-herbertenediol (not shown).56

H3CO C0 2 Et OCH 3

(±)-lagopodin A

A ring-closing metathesis strategy was also employed by Srikrishna and workers in the first total synthesis of (±)-lagopodin A, a fungal sesquiterpene.57 The authors found the sterically congested 1-aryl-1,2,2trimethylcyclopentane component especially challenging to construct. Olefin metathesis of heptadiene 64 in the presence of 5 mol % of 3 in

Chapter 5 Large-Ring Carbocycles

501

dichloromethane furnished the corresponding cyclopentene ester 65 in quantitative yield. A similar strategy was used by Kulkarni and co-workers in their 2006 report on the synthesis of (±)-ß-cuparenone, a related compound (not shown).58 Another sesquiterpene, fomannosin, has caused considerable concern in the southeastern United States due to its toxicity, especially toward certain species of pine and select symbiotic bacteria. Paquette and co-workers recently synthesized both (+)- and (-)-fomannosin from Z)-glucose in an effort to further investigate the properties of these compounds.59 Ringclosing metathesis of cyclobutyl diene precursors 66 and 68 in the presence of 5 mol% of 4 in refluxing benzene furnished the corresponding carbocyclic products 67 and 69 in 77 and 91% yield, respectively.

cT

OTBDPS

PMBtf

"OR

PhH reflux, 4 hr

i^^OTBDPS PMBCf

'"OR

67, R = MEM 77% 69, R = TBS 91%

66, R = MEM 68, R = TBS

"OH (+)-fomannosin

"OH -)-fomannosin

Srikrishna and Dethe employed a ring-closing metathesis strategy in their enantiospecific synthesis of the pacifigorgiane sesquiterpene carbocyclic core which contains a fused 6,5 system. Treatment of 70 as a mixture of diastereomers with 10 mol % of 3 in refluxing dichloromethane provided the corresponding pacifigorgia-2,7-dien-4-one 71 in quantitative yield. Srikrishna and co-workers later applied this strategy in their synthesis of functionalized bicyclo[4.3.1]decanes, which are key intermediates in the construction of vibsane diterpenoids (not shown).61

502

Name Reactions for Carbocyclic Ring Formations

CH2CI2 reflux 99%

71

pacifigorgiol

Spirocycles are found in a number of natural products with therapeutic and industrial applications. Until the development of Schrock's and Grubbs's catalysts, the formation of these desirable, rigid compounds presented a significant challenge for synthetic organic chemists. In recent years, many carbocyclic spirocycles have been prepared in high yields using ring-closing metathesis as a key step. Several examples of five-membered ring carbocyclic spirocycles are illustrated in the parargraphs below.

CH2CI2 reflux, 4 hr

99%

Dumsin, a highly complex tetranortriterpene containing 18 stereogenic centers and a spirocyclic A, A', B system, has recently gained attention due to its potential as a selective and potent pesticide. Srikrishna and Babu employed olefin metathesis as a key step in their rapid and enantiospecific synthesis of the ABC ring system of dumsin.62 Treatment of 6,6-bis-allyl carvone 72 with 5 mol % of 3 in dichloromethane provided the

Chapter 5 Large-Ring Carbocycles

503

corresponding spirocyclic A ring 73 in quantitative yield. No competeing side reactions were observed with the more sterically hindered olefin in the ring-closing step, highlighting the selectivity of 3 for less sterically demanding olefins. Srikrishna and Babu also used a similar approach to construction the C ring of dumsin, yielding the correspoinding tricyclic ABC system (not shown). Marquez and Hobson, in an effort to produce spirocycles with functional handles for diversification, synthesized several highly functionalized spirocyclic pyrans using ring-closing metathesis. 3 Reaction of bis-alkenyl compound 74 with 5 mol % of 3 in refluxing dichloromethane gave the corresponding spirocycle 75 in 85% yield. Six-, seven-, and eightmembered ring spirocycles were also prepared via this method, and the authors noted that yields decreased correspondingly with an increase in the size of the spirocycle, presumably due to the lack of conformational constraints.

a-acorneol

ß-acorneol

a-ep/-acorneol

ß-ep/-acorneol

Srikrishna and co-workers employed a similar strategy for the general synthesis of a spirocyclic core inherent to several acorneols.64 Treatment of diene 76 with 3 mol % catalyst loading of 4 in refluxing benzene provided

504

Name Reactions for Carbocyclic Ring Formations

the corresponding spirocyclic carbocycle 77 in near quantitative yield. Five additional steps were required to produce the desired acorneols. Gurjar and co-workers prepared several novel carbohydrate-based spirocycles and a spirocyclic proline derivative for applications in peptide, nucleoside, and carbohydrate synthesis.65 Ring-closing metathesis of carbohydrate diene precursor 78 furnished the corresponding spirocycle 80 in 88% yield using a catalytic amount of 3 in dichloromethane. Reaction of proline derivative 79 under similar conditions gave the corresponding spirocyclic peptide 81 in 96% yield.

CH2CI2 rt, 4 h 88%

N^OTBDPS Ts

79

CH2CI2 rt, 1.5 h 96%

OTBDPS

80

81

3 CH2CI2 rt,4-6 h

ΓΓ^Γ^

'

X

)

Λ U^R I

83, R = H 92% 85, R = C 90%

Majumdar and co-workers employed an olefin metathesis strategy in their synthesis of several spironaphthyridinone derivatives.66 Spironaphthyridinones are a class of compounds that have shown promise in the treatment of autoimmune and other immune disorders. Ring-closing

Chapter 5 Large-Ring Carbocycles

505

metathesis of 82 or 84 using 10 mol % of 3 in dichloromethane gave the corresponding spirocycles 83 and 85 in 92% and 90% yield, respectively. Hughes and co-workers employed a ring-closing metathesis strategy as a general route for the synthesis of enantiopure five-, six-, and sevenmembered ring spirocarbocycles using zizaene as a chiral auxiliary. 7 Diene precursors 86 and 88 required 15 mol % catalyst loading of 3 (added in three equal portions every 4-6 hours) in refluxing dichloromethane to achieve the desired five-membered ring spirocycles in 91 and 89% yield, respectively. The authors noted that as the size of the spirocycle increased, the yields obtained from ring-closing metathesis decreased due to conformational constraints.

CH2CI2 reflux 91%

87

TBSO OTBS CH2CI2 reflux 89%

89

Undheim and co-workers used a similar strategy to prepare an interesting class of five-, six-, and seven-membered ring spirocyclic carbocycles for use as templates in natural product synthesis.4 Reaction of 90 with 2 mol % of 3 furnished the corresponding spirocycle 91 in 53% yield. The authors were able to produce six- and seven-membered ring spirocycles of this class, but were unable to access the analogous eightmembered ring derivatives, presumably due to conformational constraints. N^OCH3 PhH or PhCH 3 rt or reflux 53%

N' 91

506

Name Reactions for Carbocyclic Ring Formations

Cyclopentanone prostaglandins have recently garnered attention as potential cancer therapeutics. Unfortunately, native prostaglandins are quickly metabolized and exhibit limited water solubility. Florent and coworkers, in an effort to prepare metabolically stable and water-soluble prostaglandins, subjected acyclic allyl alcohols 92 and 94 (as a mixture of diastereomers) to 1 mol % of 3 in the presence of dichloromethane to produce the corresponding cyclic allyl alcohol derivatives (not shown). The carbocyclic allyl alcohols were subsequently oxidized to the corresponding enones using NMO and TPAP to give 93 and 95 in 89% and 90% yield, respectively over two steps. Enones 93 and 95 were further functionalized to give the desired prostaglandin derivatives which showed good activity against L1210 leukemia cells.

»vNHTeoc R

-

1. 3, CH 2 CI 2 rt, 1 h ^LxNHTeoc

2. NMO, TPAP

92, R = (CH2)3OCH2-pFPh 94, R = (CH 2 ) 7 CH 3 O

93, R = (CH2)3OCH2-pFPh 89% 95, R = (CH 2 ) 7 CH 3 90% „C0 2 CH 3 A^PGAi

OH C0 2 (f-Bu)

C0 2 (f-Bu)

O. . 0 , x H 3 C(H 2 C)/ N (CH 2 ) 4 CH 3

PhH reflux, 36 h 86 o /o

o X H 3 C(H 2 C)/ X (CH 2 ) 4 CH 3

96

"o

97

bacillariolide II

Ghosh and co-workers used olefin metathesis as a key step in their synthesis of the carbocyclic core of e«/-bacillariolide II, an oxylipin.69 Oxylipins are densely functionalized naturally occurring bicyclic systems

Chapter 5 Large-Ring Carbocycles

507

with four contiguous stereocenters. In addition to the synthetic challenges these compounds present, several members of the oxylipin family have shown significant inhibitory activity against phopholipase A2, an enzyme that plays a key role in regulating the inflammatory response. Reaction of diene 96 with 6 mol % of 3 in benzene led to the desired cyclopentene 97 in 86% yield. Covey and co-workers used an abnormal Beckmann fragmentation/ring-closing metathesis strategy in their synthesis of 18-norA13(17)-androgens, derivatives of 3a-hydroxysteroids.™ These compounds have been shown to modulate ion channels within the central nervous systems of animals. Treatment of diene 98 in the presence of a catalytic amount 4 in dichloromethane gave the corresponding steroid 99 in 98% yield. Reaction of 99 with w-CPBA furnished the desired 18-nor-A13(17)androgen as a mixture of diasteromers (not shown).

CH2CI2 reflux, 1 h 98%

98

99

HO v 18-ηοΓ-Δ13'17'-androgens OH

HO/, A

100

Cbz

9H

^NH

Cbz

HO/„./X^.NH PhH refulx, 15 h 83%

(-)-agelastatin

101

508

Name Reactions for Carbocyclic Ring Formations

(-)-Agelastatin A is an architecturally unusual tetracyclic compound that exhibits significant antitumor activity. Ichikawa and co-workers recently improved on an earlier syntheses of (-)-agelastatin A by using ring-closing metathesis as a key step in the construction of the five-membered carbocycle core.71 Reaction of diene 100 with 5 mol % of 3 in benzene produced the corresponding highly functionalized cyclopentene ring 101 in 83% yield. This compound was converted via several steps to provide (-)-agelastatin A. The sesquiterpene merrilactone A is an important neurotrophic factor of considerable therapeutic interest for the treatment of several neurodegenerative disorders. It remains a considerable challenge synthetically due to its densely oxygenated pentacyclic architecture containing seven stereogenic centers, two γ-lactone moieties, and four quaternary carbon atoms. Mehta and co-workers recently reported on the use of a ring-closing metathesis strategy to synthesize the fused tricyclic core of merrilactone A.72 Treatment of lactone 102 with 10 mol % of 3 in dichloromethane furnished the desired tricyclic system 103 in 95% yield.

merrilactone A

Triquinane natural products have recently gained attention due to their complex architectures, and cytotoxic and antibacterial properties. Recently, Srikrishna and Beeraiah used a ring-closing metathesis strategy to n't

synthesize both the eis, syn, eis- and eis, anti, c/s-linear triquinanes. Treatment of diene 104 with 5 mol% of 3 in dichloromethane gave the corresponding eis, syn, czs-triquinane 105 in quantitative yield. A similar strategy was employed in the synthesis of the eis, anti, c/s-triquinane, with the ring-closing metathesis proceeding smoothly in 97% yeild (not shown).

Chapter 5 Large-Ring Carbocycles

CH2CI2 rt, 0.5 h 100%

509

X0 105

Six-Membered Rings A general example of the versatility of ring-closing metathesis in the formation of six-membered ring carbocycles is demonstrated by Shibasaki and co-workers, who employed their ring-closing metathesis strategy for five-membered ring carbocyclic enol ethers to six-membered ring carbocyclic enol ethers. Carbocyclic enol ether 107 was readily prepared from the corresponding electron deficient olefin 106 in 92% yield using only 7 mol % of catalyst 3 in refluxing benzene. R

R

OTMS

OTMS PhH reflux, 1 h 92%

R=C0 2 Et 106

OTBDMS

OTBDMS PhH reflux 65%

R=Ph 108

109

OTMS

110

OTMS PhH reflux 89%

111

Aggarawa and co-workers also used their ring-closing metathesis strategy for the preparation of five-membered ring carbocyclic silyl enol ethers to prepare a six-membered ring carbocyclic silyl enol ether bearing a phenyl substituent. In their study, treatment of 108 with upward of 20 mol % of 4 in refluxing benzene led to a 65% yield of the desired product 109. The authors attributed the modest yield to the lack of gem-substituents, and tested this theory by using olefin metathesis to synthesize a cyclic silyl enol ID

Name Reactions for Carbocyclic Ring Formations

510

ether bearing a simple gem dialkyl group (110). This substrate required only 10 mol % of 4 to provide the corresponding carbocycle 111 in 89% yield. Weinreb and co-workers used their olefin metathesis strategy for the preparation of chloro-cyclopentene derivatives from vinyl chlorides for the synthesis of chloro-cyclohexene derivatives.42 Vinyl chloride 112, when treated with 10 mol % of 4 in benzene, gave the corresponding cyclohexene derivative 113 in quantitative yields.

112

R = C0 2 Et

PhH, reflux 99%

2

R = CH 3 or H

R

R

113

Piscopio and co-workers pioneered a method for synthesizing functionalized carbocycles via an ester enolate Claisen/ring-closing metathesis strategy.74 Substrates 114, 116, 118, and 120 were subjected to olefin metathesis using 2.5 mol % of 3 in the presence of dichloromethane to furnish the corresponding carbocycles, including fused bicyclic (119) and spirocyclic (121) systems, in upward of 86% yield. Haudrechy and coworkers applied a similar approach to synthesize a number of highly functionalized carbocycles,75 and recently Sutherland and co-workers used an analogous aza-Claisen/ring-closing metathesis route in the preparation of functionalized carbocyclic amides (not shown).76

C0 2 Bn 114

^^ΧΌ 115 87%

2

CO2CH3 120

118 J

116

ex

CO2CH3

C0 2 Bn

3 CH2CI2 ,, rt, 1-16 h ^y

Βη

*C0 2 CH 3

C0 2 Bn 117 96%

119 86%

v

'C02CH3 121 97%

Martin and co-workers applied a ring-closing metathesis strategy in the synthesis of medium-size carbocycles fused to butyrolactones.77 Fused butyrolactones are ubiquitous in nature and play an important role in the

Chapter 5 Large-Ring Carbocycles

511

structural integrity and biological activity of many natural products. Butyrolactones 122 and 124 were subjected to ring-closing metathesis using 10 mol% of 4 in refluxing dichloromethane to furnish the corresponding α,β fused γ-lactones 123 and 125, both in 85% yield.

CH2CI2

reflux, 3 h 122, R1 = S0 2 Ph, R2 = H 124, R1 = S0 2 Ph, R2 = CH3

123, R1 = S0 2 Ph, R2 = H 85% 125, R1 = S0 2 Ph, R2 = CH3 85%

Spino and co-workers employed a relay ring-closing metathesis strategy using a chiral auxiliary in their enantioselective synthesis of several amino carbocycles.78 Treatment of diene 126 with a catalytic amount of 3 in refluxing dichloromethane gave the corresponding aromatic allyl amine 127 in quantitative yields as a single enantiomer with concomitant loss of the chiral auxiliary. Boc BocHN CH2CI2 reflux 99%

126

127

CH2CI2 rt, 12 h

128, R1 = CH 3 , R2 = H 1

2

129, R1 = CH 3 , R2 = H 84%

130, R = CH 3 , R = CH 3

131, R1 = C H 3 , R2 = CH 3 92'

132, R1 = Ph, R2 = H

133, R1 = Ph, R2 = H 86%

Loh and co-workers used olefin metathesis to synthesize a number of homoallylic amines, which serve as important intermediates in the synthesis of alkaloid natural products and nitrogen heterocycles.79 Reaction of substituted dienes 128, 130, and 132 with 10 mol % of 4 in dichloromethane provided the corresponding amines in high yield (84-92%).

512

Name Reactions for Carbocyclic Ring Formations

A number of research groups have used ring-closing metathesis to prepare conformationally constrained a- and ß-amino acids containing sixmembered ring carbocycles. Several key examples are discussed in the paragraphs below. Abell and co-workers applied their ring-closing metathesis strategy for the synthesis of ß-amino acid residues constrained by five-membered carbocycles to produce a host of ß-amino acid residues constrained by sixmembered ring carbocylcles.46 Treatment of the dienes 134, 136, and 138 with a catalytic amount of 3 in refluxing benzene provided the corresponding constrained ß-amino acids in upwards of 90% yield. In a later report, they were able to verify the yields of these compounds using 4 under similar reaction conditions, and expanded their work to synthesize a host of five-, six- and seven-membered ring cyclic ß-amino acid analogs (not shown).80

CbzHN H3C02C

R

134, R = H 136, R = CH3 138, R = Et

PhH reflux

CbzHN'^T H3C02C 'R 135, R = H 96% 137, R = CH3 96% 139, R=Et 94%

Ring-closing metathesis has also been applied to the synthesis of a number of carbasugars containing six-membered rings. Many of these carbacycles are natural products; however, several unnatural carbasugars have also been prepared and evaluated for their potential to serve as biological mimics of natural pyranose sugars. Many carbasugars have gained attention as potent glycosidase inhibitors, while others have been used as precursors in the synthesis of higher order natural products. Several examples highlighting the diversity of six-membered ring carbasugars are illustrated below. A number of carbocyclic mimetics of pyranose carbohydrates have been prepared using ring-closing metathesis as a key step. One of the first examples by Madsen and co-workers, employed a novel zinc-mediated domino reaction to convert 5-iodo-ribofuranosides to the corresponding diene precursors 140 and 143 (not shown).81 These diene precursors were then subjected to ring-closing metathesis using up to 10 mol% of 3 in the presence of dichloromethane to provide the corresponding carbasugar derivatives 141 and 143 in near quantitative yields. Dihydroxylation of compounds 141 and 143 using OSO4 provided the corresponding carbasugars (+)-ta/o-quercitol and (-)-ga/a-quercitol (not shown) in high yeilds. Their report signified the

Chapter 5 Large-Ring Carbocycles

513

shortest enantioselective synthesis of both these compounds, and the authors were able to extend this approach to synthesize a number of other derivatives.

CH2CI2 rt 96%Ό

HCT ^ V '"OH

CH2CI2 rt 95%

HOxV V "*OH OH

HO, HO*' V " ^ ' ' O H ÖH (+)-fa/o-quercitol

OH 141

OH

143

ΗΟ^ Ύ' "OH ÖH (-)-gala-quercitol

Since Madsen's initial report, several additional pyranose carbacycles have been synthesized. Vankar and co-workers synthesized mwco-quercitol, (+)-ga/a-quercitol, and 5-amino-5-deoxy-D-vz'Z>o-quercitol, from D-mannitol using olefin metathesis as a key step.82 The later compound, 5-amino-5deoxy-D-vz'èo-quercitol is especially noteworthy as it an important component of a number of aminoglycoside antibiotics. Van Boom and coworkers used olefin metathesis in the synthesis of 2-deoxystreptamine, a important carbohydrate component of neomycin B and kanamycin B, two aminoglycoside antibiotics.83 Gallos and co-workers also employed a ringclosing metathesis approach in their synthesis of 6a-carba-ß-Dfructopyranose, a potential sweetener.84 Kumaraswamy and co-workers used a similar approach in their preparation of glucose and galactose based carbacycles as intermediates in drug development.85 And finally, Cumpstey and co-workers recently published the synthesis of two ß-hexosaminidase inhibitors, valienamine and 1-epz'-valienamine from either D-glucose or Lsorbose,86 or D-mannose87 using ring-closing metathesis as the key step in their syntheses.

Name Reactions for Carbocyclic Ring Formations

514

H0

OH

HON'

"d NH2

Y"^OH 'NH 2 H C T ' N r ^ OH OH ÖH .. . 5-amino-5-deoxy2-deoxymuco-quercitoi o-wöo-quercitol streptamine

BnO^""^

ΒηΟ^Ν^

H3CO^'Y

Η300^'γ

OH

HO" ' ' - O H 6a-carba-ß-D fructopyranose

HO"~V^VNH2 Η Ο ^ ' Υ ' 'ΌΗ

OH

OH

glucose-based galactose-based carbasugar carbasugar

valienamine

HO 1-ep/'-valienamine

In 2004, Halcomb and co-workers reported the first successful synthesis of an isostere of an 0-linked glycopeptide in an effort to study how sugar modifications affect protein folding in inflammatory diseases and cancer.88 Treatment of diene 144 with 10 mol % of 4 in refluxing toluene produced the desired product 145 in 76% yeild as a mixture of diastereomers. OPMB 1

N ^

4

OPMB

ΡΜΒΟ^γΧγ°Η

PhCH3 reflux 76%

OPMßk^

144 AcO"^

ΡΜΒ0-"~Ν^γ0Η

f"

AcO*'\

- /

S

^

Ρ Μ Β Ο * ' γ / ^ 'ΌΡΜΒ OPMB 145

R

"OAc OAc

R= W-Boc-•Gly-Cys-Phe-OEt

ce-galactosyl glycopeptide isostere

Holt and co-workers used olefin metathesis to synthesize a number of enantiomerically pure annulated carbohydrate systems containing carbocycles, as precursors for the synthesis of taxoids and other natural products.89 Treatment of dienes 146 and 148 with a catalytic amount of 3 in benzene gave the corresponding 6,6,6-carbocycles, c/s-147 and trans-149, in 89 and 80% yield, respectively. The authors attempted a similar strategy to prepare 6,6,5-annulated systems; however, they achieved little to no yield of the desired products, presumably due to ring strain. Holt and co-workers

Chapter 5 Large-Ring Carbocycles

515

followed up on their initial report, using a similar strategy to prepare a host of 6,6,6-, 6,6,7-, and 6,6,8-, and 6,6,9-membered ring carbocyclic systems as r well as several oxygen containing spirocycles (not shown).90 H

<X

Λ \ΟΟΗ 3

,ΛΟΗ

PhH reflux, 17 h 89% 147

PhH reflux, 17 h 80%

Korinenko and co-workers used ring-closing metathesis as a key step in their synthesis of several analogs of pancratistatin, a potent anticancer natural product.91 Dienes with varying aryl substituents (150) were prepared and subjected to ring-closing metathesis using 3 mol % of 3 in dichloromethane to furnish the corresponding carbocycles in 80-95% yields. QBn BnCv^^DBn

ΑΛΛ

CH2CI2 rt, 12 h 80-95%

II 150

Ar

H 3 CO"

- ^ Λ ^

H3CO H„r.rr

X

OBn BnOv / ^ . O B n

3

^ χ ^

Ar'

u 151

i* e

(Γ^[* Kr I

X

CO

OCH-,

X ci

Ring-closing metathesis has also been applied to the synthesis of a number of terpene derivatives containing six-membered rings. The terpene derivatives prepared by this approach have been as simple as cuparene and as complex as tricycloillicinone. Several key examples are illustrated below.

Name Reactions for Carbocyclic Ring Formations

516

Prasad and co-workers employed ring-closing metathesis as a key step in their synthesis of (±)-cuparene. Diene precursor 152 underwent quantitative conversion to the corresponding carbocycle in refluxing benzene using only 3 mol % catalyst loading of 4. Dehydration and aromatization of the corresponding tertiary alcohol (not shown) gave the desired product in high yield.

PhH reflux, 0.5 h

99%

152

153

(±)-cuparene

Ring-closing metathesis was also used as a key step in the enantioselective synthesis of (+)-carissone, a eudesmane sesqueterpenoid, by Stoltz and co-workers.93 Reaction of enone 154 with 3 mol % of 4 in benzene gave the corresponding carbocycle 155 in quantitative yields. Seven additional steps were required to access (+)-carissone (not shown). , ^ \ ^

OTBS

OTBS

PhH, 40 °C, 99%

154

155

(+)-carissone

Saicic and co-workers used olefin metathesis as one of the final steps in their synthesis of (±)-periplanone C, a C-macrolide pheromone.94 aHydroxy ketoester 156, when treated with 3 mol% of 3 in dichloromethane at room temperature over the course of 23 h, gave the desired carbocyle 157 in 81% yield. The authors applied this methodology to access a number of other intermediates in the periplanone family.

Chapter 5 Large-Ring Carbocycles

.CO2CH3

517

H3CO2C. CH2CI2 rt, 23 h 81%

156

157

periplanone C

OTBDMS

OTBDMS CH2CI2 rt, 24 h 91-93%

158

159

OTBDMS

160

s ^

n

'

0CHa X

OH

(+)-ottelione A

OTBDMS CH2CI2 rt, 24 h 86%

161

Χχ^ OH

(-)-ottelione B

Clive and Liu used a ring-closing metathesis strategy to access the six-member ring carbocyclic components of the anticancer agent's ottelione A and B.95 Olefm metathesis of 158 or 160 with catalytic amount of 3 in the presence of dichloromethane provided the corresponding carbocycles 159 and 161 in 93 and 86% yields, respectively. The authors also attempted this

518

Name Reactions for Carbocyclic Ring Formations

reaction using similar reaction conditions with 4; however, they found no improvement in the overall reaction yields (not shown). Srikrishna and co-workers employed ring-closing metathesis as a general strategy for the preparation of the 6,6,5-tricyclic core of the elisabethane diterpenes, a family of compounds which exhibit a wide range of biological properties.96 It is interesting that ring-closing metathesis of 3,4,4-trisallylcarvone 162 in the presence of 5 mol % of 3 in refluxing dichloromethane did not proceed as expected to provide the desired tricycle 163. However, olefin metathesis of trisallylcarveol 164 proceeded smoothly under similar conditions to give the targeted tricyclic system 165 in 40% yield, highlighting the importance of the allyl alcohol in substrate activation.

CH2CI2 reflux NR

CH2CI2 reflux 40%

164 sOAc

OAc

166

CH2CI2 rt, 9 h 94%

167

o

tricycloillicinone

Tricycloillicinone is a novel C6-C3 prenylated compound with an interesting 3,4,4-trimethyltricyclo[5.3.1.01,5]undecane ring. This compound has recently attracted attention for its ability to increase choline acetyltranferase activity and as such may hold promise as a therapeutic for

Chapter 5 Large-Ring Carbocycles

519

the treatment of neurological disorders. Recently, Srikrishna and co-workers employed a ring-closing metathesis approach to synthesize the tricyclic carbocyclic core of tricycloillicinone.97 Reaction of acetate 166 with 10 mol % 3 in dichloromethane provided the corresponding tricyclic acetate 167 in 94% yield. Ongoing efforts by Srikrishna and co-workers are focusing on the transformation of this compound to the desired tricycloillicinone product. Kim and co-workers applied an olefin metathesis strategy in the total synthesis of (-)-perrottentinene, a biogeneic precursor to of (-)-A]-transtetrahydrocannabinol.98 Treatment of diene precursor 168 with a catalytic amount of 4 in the presence of refluxing dichloromethane gave the desired product 169 in 90% yield. Their report signified the first successful example of olefin metathesis using a proximal o-phenol group.

CH2C12

reflux, 16 h 90% 168

"OH perrotetinene

Olefin metathesis was also employed by Trost and Dogra in the synthesis of (-)-Δ -frvms-tetrahydrocannabinol, the psychomimetic component of marijuana." Treatment of 170 as a mixture of diastereomers with a catalytic amount of 4 gave a mixture of the corresponding anti-171 and syn-112 cyclohexenes. Equilibration in sodium methoxide and methanol over the course of 3 days gave almost exclusively the anti product. Four additional steps were required to achieve (-)-A9-ira«s-tetrahydrocannabinol.

520

Name Reactions for Carbocyclic Ring Formations H 3 C0 2 C, OCH·,

NaOCH3 CH3OH 65 C, 3 d π C5fiH 11

(-)-Δ -trans-tetrahydrocannabinol

fumagillin

Fumagillin and several related analogs have been shown to inhibit angiogenesis, and as such are of interest as potential treatments for cancer. Watson and co-workers recently employed a ring-closing metathesis strategy using a chiral auxiliary to enantioselectively construct the cyclohexene core of fumagillin.100 Diene 173, where R = H, when subjected to ring-closing metathesis using 5 mol % of 3 in dichloromethane, provided the corresponding carbocyclic ring 174 in 88% yield as a single enantiomer. Interestingly, diene 175, where R = Ph, failed to undergo ring-closing metathesis. The authors did not speculate as to why the reaction failed; however, it is likely that sterics may have played a role. Spirocycles incorporating six-membered rings are important synthons in organic synthesis. These structural motifs have also been found in a

Chapter 5 Large-Ring Carbocycles

521

number of natural products. In general, six-membered ring carbocycles can be readily prepared in high yields using olefin metathesis. Several examples of the synthesis of six-membered ring carbocycles are illustrated below. In 2008, Gals and co-workers reported a general method for the synthesis of asymmetric spiroketals, which are important intermediates in the synthesis of a number of biologically active compounds.101 α,α-Dienyl dihydropyrans 177 and 179 underwent ring-closing metathesis using a catalytic amount of 4 in dichloromethane to provide the corresponding spirocyclic carbocycles 178 and 180 in high yields. The authors observed that the Lewis basic sulfoximine group had little effect on the ring-closing metathesis reaction.

Grubbs, Stoltz, and co-workers used olefin metathesis as a key step in Elatol, a the first catalytic asymmetric total synthesis of elatol.102 chamigrene sesquiterpene with antibiofouling, antibacterial, antifungal, and cytotoxic properties, is a particular challenge synthetically due to its sterically congested spirocyclic system, exocyclic olefin, vinyl halide and

Name Reactions for Carbocyclic Ring Formations

522

c/s-halohydrin functionality. Treatment of α,ω-diene 181 with 5 mol % of 6 in benzene gave the corresponding chloroalkene 182 in 97% yield. Four additional steps were required to access the desired natural product. Kim and and co-workers used ring-closing metathesis to construct the (-)-Lepadiformine is a tricyclic spirocyclic core of (-)-lepadiformine.10 perhydropyrrolo[2,l:/]quinolone that has recently gained attention due to its moderate in vitro tumor cell cytotoxicity and positive cardiovascular effects. Treatment of diene 183 with a catalytic amount of 4 in the presence of refluxing dichloromethane furnished the corresponding azaspiro cyclohexene 184 in near quantitative yield.

OTBDPS / BnO

OTBDPS

CH2CI2 reflux, 1 h

/ BnO

98%

183

184

(-)-lepidformine

Martin and co-workers employed a ring-closing metathesis strategy in their total synthesis of the azatricyclic skeleton of FR01483.104 (-)-FR01483 is an immunosuppressant that has been shown to prolong graft survival time by inhibiting purine nucleotide synthesis. Reaction of 185 as a mixture of dienes with 10 mol % of 4 in dichloromethane gave a separable mixture of the corresponding azaspiro cyclohexene derivatives 186 and 187 in near quantitative yield. Unfortunately, the desired diastereomer, 186, was produced as the minor product; however, their report constituted an improvement over their previous work on this compound.105

NTroc TBDPSO

CH2CI2 rt, 99%

NTroc

NTroc TBDPSO^

TBDPSÖ 185

OTBS

OTBS

OTBS

186

(45:55)

187

Chapter 5 Large-Ring Carbocycles

523

OCH·, H 3 0 2 PO

FR901483

Brimble and Trzoss used a double-alkylation/ring-closing metathesis approach to synthesize several spiroimines.1 6 Spiroimines are important functional moieties in a number of shellfish toxins suchs as gymnodimine. Lactams 188, 190, and 192 were subjected to ring-closing metathesis using 5 mol % of 3 in dichloromethane to furnish the corresponding 5,6-(189), 6,6(191), and 7,6-(193) spirolactams in upwards of 85% yield.

CH2CI2 rt, 3 h 188, n = 1 190, n = 2 192, n = 3

189, n = 1 86% 191, n = 2 90% 193, n = 3 88%

gymnodimine

CH2CI2 rt, 1 h 96%

(-)-quinic acid

195

524

Name Reactions for Carbocyclic Ring Formations

Pansare and Adsool employed a ring-closing metathesis strategy in their synthesis of (-)-quinic acid.107 Quinic acid is an important regulator in the biosynthesis of aromatic compounds via the shikimic pathway, and may serve as a potential antifungal, antibacterial and antiparasitic. Ring-closing metathesis of diene 194 using 7 mol % of 3 in dichloromethane gave the corresponding spiro-morpholinone 195 in 96% yield. Hughes and co-workers extended their ring-closing metathesis strategy for the synthesis of enantiopure five-membered ring spirocylcles using zizaene as a chiral auxiliary to the synthesis of enantiopure sixmembered ring spirocarbocycles.67 Diene precursor 196 required 15 mol % catalyst loading of 3 in refluxing dichloromethane to achieve a near quantitative yield of the desired spirocycle 197.

CH2CI2 reflux 97%

196

Undheim and co-workers applied their olefin metathesis strategy for the synthesis of five-membered ring spirocyclic carbocycles to synthesize six-membered ring spirocyclic carbocycles for use as templates in natural product synthesis. Reaction of 198 with 2 mol % of 3 furnished the corresponding spirocycle 199 in greater than 95% yield. /TO

N.,OCH3 \

PhHorPh rt or reflux > 95%

Frejd and co-workers used a ring-closing metathesis strategy as the key transformation in their synthesis of several novel spiro-cyclohexene bicyclo[2.2.2]octane derivatives.108 Spiro-cyclohexene bicyclo[2.2.2]octane derivatives are rare molecular frameworks, with only a few examples reported to date. Olefin metathesis of diastereomeric homoallylic alcohols 200 and 202 using 10 mol % of 3 in refluxing dichloromethane provided the corresponding spirocyclic carbocycles 201 and 203 in 84 and 85% yields, respectively.

Chapter 5 Large-Ring Carbocycles

ΌΒη H3CO

525

ΌΒη

CH2CI2 reflux 84%

H3CO

201

200

CH2CI2 reflux 85%

-

0°™ s

H 0 ^ 0 B „ H3CO 203

202

Singh and co-workers recently reported a general method for the synthesis of embellished spiro-fused bicyclo[2.2.2]octane systems using a Diels-Alder cycloaddition/ring-closing metathesis route.109 These systems, which are key intermediates in the synthesis of atisane diterpenoides such as serofenic acid A, have been shown to possess neuroprotective activity. Treatment of allyl alcohol 204 with 10 mol % of 3 in dichloromethane provided the corresponding spirocyclic carbocycle 205 in 86% yield. The authors also prepared seven- and eight-membered ring analogs of 205.

'ΌΗ 205

serofenic acid A

Dysinosin A is a highly oxygenated novel inhibitor of thrombin and factor Vila. Hanessian and co-workers employed a ring-closing metathesis strategy in their preparation of the 6,5-fused core of dysinosin A.110 Olefin metathesis of 206 and 208 using only 1 mol % of 4 gave quantitative yields

526

Name Reactions for Carbocyclic Ring Formations

of the desired carbocycles 207 and 209. Several additional steps were required for the construction of the final target. CO3CH3

CO3CH3

CH2CI2 rt 99%

206, R = Boc 208, R = Cbz HO,

R 207, R = Boc 209, R = Cbz

dysinosin A

Θ

OSO3

H3CO'

A similar strategy was employed by Robichaud and Termblay in the enantioselective synthesis of (+)-compactin, a hydroxymethyglutaryl coenzyme A (HMG-CoA) reductase inhibitor. Olefin metathesis of trienes 210 and 212 in the presence of a catalytic amount of 4, provided the corresponding conjugated dienes 211 and 213 in 86% and 71% yield, respectively.

CH2CI2 reflux TMS 86% BDMS 7 1 %

210, R = TMS 212, R = BDMS

(+)-compactin

Enev and co-workers employed olefin methathesis in their approach to the cz's-decalin core of branimycin, an antibiotic."2 Until their report in 2008, preparations of branimycin almost exclusively employed the use of

527

Chapter 5 Large-Ring Carbocycles

Diels-Alder reactions to construct the c/s-decalin system. Metathesis of triene 214 in the presence of 5 mol % of 4 in toluene gave the corresponding cw-decalin system 215 in quantitative yields. The authors reported on the ring-closing metathesis of several additional trienes differing only in the stereochemistry of the groups with similar success. PMBO

H

OH

PMBO

H

OH

PhCH3 H

II

5 0

-ODPS

°

ODPS

c

99%

R=Si(CH3)2Ph

HQ

214

OCH·,

215

H3CO

ft ^ H 3 C O

O'

branimycin

CH2CI2 reflux NR

CH2CI2 reflux 74-90% 218

(-)-artemisinin

Dudley and co-workers used a relay ring-closing metathesis strategy in the synthesis of (+)-dihydro-epz'-deoxyarteannuin B, a key biogenic

528

Name Reactions for Carbocyclic Ring Formations

precursor in the synthesis of artemisinin.113 Initially, they attempted olefin metathesis of diene 216 using a catalytic amount of 3 in refluxing dichloromethane; however, the expected carbocylic product 217 was not obtained. The authors speculated that steric congestion might be the cause of the failed cyclization. Exentsion of 216 to provide 218 followed by relay ring-closing metathesis using a catalytic amount of 3 under similar conditions gave the desired tricyclic system 219 in 74-90% yield (multiple attempts). Castle and co-workers used a ring-closing metathesis strategy in their synthesis of the carbocyclic core of (±)-hasubanonine, a member of the hasubanan alkaloid family.114 Hasubanan alkaloids are of interest due to their structural similarity to morphine alkaloids. Treatment of diene 220 with a catalytic amount of 4 in refluxing dichloromethane furnished the desired phenanthrene core 221 in quantitative yield. Six additional steps were required to obtain the desired natural product.

OCH,

CH2CI2 reflux 99%

OCH·,

η

""NCH3 c r ^f "0CH3 0CH3 (±)-hasubanonine

Wipf and co-workers employed olefin metathesis in their synthesis of (±)-thiohalenaquinone. (±)-Thiohalenaquinone is of particular interest due to its complex carbocyclic core and wide range of biological activities. In particular, it has been shown to inhibit protein tyrosine kinase, phosphatidylinositol 3 kinase, and Cdc25B dual specificity phosphatase. Ruthenium catalyzed bond migration, followed by ring-closing metathesis of diene 222 using 20 mol% of 6 in refluxing dichloromethane, provided the corresponding pentacyclic core 223 in 56% yield over two steps. Oxidation of 223 provided (±)-thiohalenaquinone (not shown).

529

Chapter 5 Large-Ring Carbocycles H3CO

H3CO. 0CH

3

1. (CO)RuHCI(PPh3)3 PhH, reflux

^

si?

"OCH·,

2. 6, CH 2 CI 2 reflux 56% (two steps) HO H3CO

223 OCH·,

(±)-thiohalenquinone

Smith and co-workers employed ring-closing metathesis to synthesize a host of benzoporphyrins." Benzoporphyrins are particularly attractive in medicine as agents for photodynamic therapy, and in industry for use as electro-optic materials. Treatment of diene 224 with a catalytic amount of 4 in dichloromethane provided the corresponding porphyrin analog 225 in good yield. Oxidation of 225 with DDQ (not shown) furnished the desired benzoporphyrin in nearly quantitative yield. The authors reported on the synthesis of several additional monosubstituted and trisubstituted derivatives as part of their study.

224

225

Name Reactions for Carbocyclic Ring Formations

530

Seven-Membered Rings Ring-closing metathesis has been most useful in the synthesis of larger carbocycles, such as seven-membered rings. Seven-membered ring carbocycles are found in a number of biologically active natural products, but have proven difficult to prepare in high yields using standard ring forming strategies. The development of ring-closing metathesis as a tool for the construction of these systems has provided for the synthesis of a host of structurally diverse compounds and natural products incorporating sevenmembered ring systems, often in high yield. The following section highlights a number of these examples. Shibasaki and co-workers used a ring-closing metathesis approach to prepare seven-membered rings from electron-deficient olefins.37 Reaction of acyclic enol ethers 226 and 228 with 7 mol % of 3 in benzene provided cyclic enol ethers 227 and 229 in 88 and 93% yield, respectively. OTMS

TMSO PhH reflux, 1 h 88%

R=CO z Et

227

226 OTMS

230

R

PhH reflux, 1 h 93%

R=C02Et 228 Ph

TMSO

R

229

OTBDMS

OTBDMS

4 PhH reflux 45%

231

Ph

Aggarawa and co-workers applied their strategy for the synthesis of five- and six- membered ring carbocyclic silyl enol ethers to the the synthesis of seven-membered ring carbocyclic silyl enol ether bearing a phenyl substituent. Substrate 230 required upward of 20 mol % of 4 in refluxing benzene to achieve modest yields of the desired product 231. Paley and co-workers used enantiopure r|4-(l-sulfinyldiene)iron(0) tricarbonyl complexes as templates for the enantioselective construction of IO

Chapter 5 Large-Ring Carbocycles

531

carbocyles via a ring-closing metathesis strategy.117 Enantiopure homoallyl alcohol adduci 232, when treated with 8 mol % of 3 in toluene, gave the corresponding seven-membered ring carbocyle 233 as a single enantiomer in 90% yield. This strategy was also applied to form eight- and nine-membered ring carbocycles with similar success.

O Fe(CO) 3 H 3 CO

PhCH 3 90%

R = MOM 232

CH2CI2 reflux, 16 h 61%

,C0 2 Me

,C0 2 Me CH2CI2 reflux, 16 h 72%

236

237

Funk and co-workers employed a ring-closing metathesis strategy in their synthesis of fused haloethyl vinyl ketones.118 These compounds are important synthetic intermediates in the production of a number of natural and unnatural products. Treatment of the five (234)- or six (236)-membered enone with a catalytic amount of 4 in the presence of refluxing dichloromethane gave the corresponding vinyl ketones 235 and 237 in 61% and 72% yield, respectively. The reported yields were based on a two step process with the first step, a retrocycloaddition of the dioxin precursor catalyzed by ZnCk, giving rise to the enone (not shown). Martin and co-workers applied their ring-closing metathesis strategy for the preparation of 5,6-fused-y-butyrolactones to 5,7-fused-ybutyrolactones. Diene precursors 238 and 240 were subjected to ring-

532

Name Reactions for Carbocyclic Ring Formations

closing metathesis using 10 mol % 4 in refluxing dichloromethane to produce the corresponding α,β-fused y-lactones 239 and 241 in 85 and 89% yield, respectively. S0 2 Ph CH2CI2 reflux, 3 h 85% 239

SPh CH2CI2 reflux, 3 h 89%

241

240

A number of research groups have used ring-closing metathesis to prepare a- and ß-amino acids constrained by seven-membered ring carbocycles. Several examples of the synthesis of these interesting molecules are provided in the following paragraphs. Kotha and co-workers used an olefin metathesis strategy in their synthesis of a conformationally constrained seven-membered ring carbocyclic α-amino acid derivative.43 Treatment of 242 with 10 mol % of 3 in refluxing toluene provided the corresponding carbocycle 243 in 69% yield. NHBoc CONH(L)PheOCH 3

NHBoc CONH(L)PheOCH 3 242

phCH

reflux 69%

243

Abell and co-workers applied their ring-closing metathesis strategy for the synthesis of ß-amino acids constrained by five- and six-membered rings to synthesize a seven-membered ring ß-amino acid for incorporation into β-peptide mimetics.46 Treatment of diene 244 with a 5 mol % of 4 in benzene provided the corresponding ß-amino acid derivative 245 in 96% yield.

533

Chapter 5 Large-Ring Carbocycles

BocHN

C02CH3

PhH rt 96%

244

BocHN H 3 C0 2 C

245

Davies and co-workers also employed a ring-closing metathesis strategy in their preparation of a constrained seven-membered ring ß-amino acid derivative.11 Treatment of lactam precursor 246 with 4 mol % of 3 in refluxing dichloromethane gave the corresponding carbocyclic ß-amino acid derivative 247 in 93% yield with greater than 95% diastereoselectivity. PhCH2CI2 reflux, 12 h 93%, > 95% de 246

tf 247

A number of seven-membered ring carbacyles have also been prepared using ring-closing metathesis as a key strategy. Many of these carbacycles are natural products or important synthons for the production of natural products. Several key examples are highlighted below.

-n

HO

ΒηΟ-^ΥΛOBn BnO

BnO 248

OBn

CH2CI2 rt, 48 h 86% OBn

Zhang and co-workers used an olefin metathesis stragtegy in their preparation of 8-oxa-bicyclo[3.2.1]octane derivatives from D-arabinose.120 Treatment of diene 248, prepared in three steps from D-arabinose, with a catalytic amount of 3 in dichloromethane provided the corresponding

534

Name Reactions for Carbocyclic Ring Formations

cycloheptene products 249 and 250 in 86% yield as a mixture of diastereomers. In 2000, Hanna and co-workers employed a ring-closing metathesis strategy for the preparation of seven-membered ring carbasugars from methyl 6-deoxy-6-iodo-3,4-isopropylidene-2-0-(fór/-butyldimethyl-silyl)-Dgalactopyranoside and methyl 6-deoxy-6-iodo-l,2:3,4-di-0-isopropylideneD-galactopyranoside in high yields (not shown).121 Later, in 2001, Hanna and Boyer used this strategy to synthesize (+)-calystegine B2, a member of a family of compounds known for their nutritional mediation properties in the plant rhizoshpere.122 Ring-closing metathesis of 251 in the presence of 8 mol % of 3 in dichloromethane furnished the corresponding carbasugar in near quantitative yield. Oxidation, followed by hydrogenolysis and deprotection (not shown) led to the production of the desired product. Madsen and Skaanderup applied a similar strategy in their 2001 synthesis of (+)calystegine B2 (not shown).

CH2CI2 rt 97%

251

HO

HO

N-Bn H

BnO 252

"AA HÒ

calystegine B 2

In 2002, Marco-Contelles and Opazo124 used an alternative ringclosing metathesis strategy in an effort to improve on the 2001 syntheses of (+)-calystegine B2, with limited success. Acetate 253 was subjected to ringclosing metathesis using 10 mol % of 3 in dichloromethane to furnish the corresponding carbacycle 254 in only 8% yield. Reaction of ketone 255 under similar conditions using Ti(0/-Pr)4 as a promoter, led to the production of the desired carbacycle 256 in only 4% yield. The authors hypothesized that the low yields were due to steric interactions between the catalyst and the functional groups on the carbacycle.

535

Chapter 5 Large-Ring Carbocycles AcO

BnO,,./Sx BnO'

N-Bn BnC> / Cbz

CH2CI2 rt, 3 d 8%

A)

BnO'

253

O

3, Ti(0;-Pr) 4 N-Bn / BnC> Cbz 255

CH2CI2 rt, 4 %

N-Bn

Bn0^u / Cbz 254

'Ù

BnO/ BnO'

z

BnC

W

M^Bn

Cbz 256

Csuk and co-workers employed a ring-closing metathesis strategy in their total synthesis of calystegine A7, another member of the calystegine family.125 Olefin metathesis of diene 257 using 10 mol % of 3 in dichloromethane gave the desired cycloheptene derivative 258 in 80% yield. BnO/,,

BnO N-Bn Cbz

CH2CI2 rt, 24 h 80%

B n 0

N-Bn ^ / Cbz 258

257 HO/,,

HO calystegine A 7

Holt and co-workers applied their ring-closing metathesis strategy for the synthesis of annulated carbohydrate systems contining six-membered rings to the synthesis of enantiomerically pure annulated carbohydrate systems containing seven-membered ring carbocycles.90 Treatment of dienes 259 and 261 with a catalytic amount of 3 in refluxing benzene gave the corresponding 6,6,7-carbocycles, cis-260 and trans-262, in 89% and 80% yield, respectively.

Name Reactions for Carbocyclic Ring Formations

536

(X

Λ ΝΟΟΗ 3

ΛΟΗ

PhH reflux, 17 h 89%

Ρ^

-o

H,

260

PhH reflux, 17 h 80%

261

262

A number of terpenes and terpenoids bearing seven-membered rings have also been synthesized using an olefin metathesis strategy. Several examples are highlighted below. Ring-closing metathesis was employed by Shishedo and co-workers in their total synthesis of (+)-sundiversifolide, a herbicide.126 Treatment of enone 263 with 5 mol % of 4 in refluxing dichloromethane furnished the corresponding α/β unsaturated ketone 264 in 95% yield.

o

Ύ

263

CH2CI2 reflux 95%

HO" \ ^ X _ V

264

Ή

(+)-sundiversifolide

Nosse and co-workers used ring-closing metathesis to synthesize a 5,7,5-fused lactone.127 These tricyclic frameworks are the core components of the thapsigargin family, a family of sesquiterpene lactones with the ability to restore apoptotic function in cancer cell lines. Thapsigargins are currently under investigation as potential therapeutics for the treatment of prostate cancer. Reaction of lactone 265 with 10 mol % of 4 and a catalytic amount of TBAF in toluene while irradiating at 300 W gave the corresponding tricyclic system 266 in near quantitative. The authors noted that nitrogen sparging to remove ethylene was required to force the equilibrium of the reaction towards the product. Nosse's work presented a slight improvement

Chapter 5 Large-Ring Carbocycles

537

over Ley's 2003 report using a similar approach to construct the same tricyclic core (not shown).128

4, TBAF PhCH 3 300W uW 1.5h 98%

266 OAc

R1=octanoyl R2=butanoate O thapsigargin

Krafft and co-workers used olefin metathesis to prepare several inside-outside medium-size rings as scaffolds for natural products synthesis.129 Reaction of bicyclic lactone 267 with 10 mol % of 4 in refluxing dicholormethane gave the corresponding tricyclic lactone 269 in 88% yield after only two hours.

CH2CI2 reflux, 2 h 88% 267

268

Mehta and Lakshminath employed a ring-closing metathesis strategy to generate the seven-membered ring carbocycle of the tricyclic core of rameswaralide as part of their ongoing efforts to synthesize this compound.130 In addition to having a complex and highly functionalized 5,7,6-fused tricarbocyclic core incorporating a stable enol functionality and six stereogenic centers, ramewaralide is a potential anti-inflammatory compound with activity against TNF-α, IL-15, IL-5, and COX2. Treatment of enone 269 in the presence of 10 mol % of 4 in dichloromethane gave the corresponding tricyclcic system 270 in 90% yield. Srikrishna and Dethe

Name Reactions for Carbocyclic Ring Formations

538

employed a similar ring-closing metathesis strategy for the BC and AB rings of rameswaralide (not shown).131

i=0 >OTES

rameswaralide

Ring-closing metathesis has also been applied to the synthesis of a number of terpene derivatives containing seven-membered rings. Several key examples are illustrated below. Tori and co-workers used ring-closing metathesis as a key step in their synthesis of several sphenolobane-type diterpenoids in an effort to determine the absolute configuration of these compounds. Higher yields were observed when 271, 273, and 275 were reacted with 1 in the presence of toluene, in comparison to 3 in refluxing dichoromethane. However, twice the molar percentage of 1 was required. 3, CH2CI2 reflux, 24 h

EtOoC

271,R = TES 273, R = OAc 275, R = MOM

or 1,PhCH 3 60 °C, 24 h

Et0 2 C

^^^

R O ^ ^ ^ 272, R = TES 3-94%, 1-99% 274, R = OAc 3-61%, 1-84% 276, R = MOM 3-21%, 1-37% OH

sphenolobane diterpenoids

Chapter 5 Large-Ring Carbocycles

539

Olefin metathesis was also used as a key step in Wicha and coworkers synthesis of the carbocyclic core of several di- and sesquiterterpenes. 133 Reaction of 277 with 5 mol % of 4 in refluxing benzene gave the corresponding bicyclic system 278 in 60% overall yield. Me02C H

'"■

Me0 2 C LI

H

H

-*

PhH reflux, 16 h 60% 277

278

Mehta and Likhite employed an olefin metathesis approach in their synthesis of (±)-frondosins A and B.134 These novel meroterpenoids have shown promise as therapeutics for the treatment of inflammatory diseases. Ring-closing metathesis of 279 and 281 in the presence of a catalytic amount of 3 in refluxing benzene gave the corresponding bicyclic tertiary alcohols 280 and 282 in 75 and 85% yields, respectively. OMe MeO

H

\

OTBS

PhH reflux, 16 h 80%

279 OMe

PhH reflux, 12 h 75%

MeO

H

)

OTBS

282

540

Name Reactions for Carbocyclic Ring Formations

frondosin A 136

1 Cha and co-workers1JO used cyclopropanols,135 " in an effort to determine the conformational constraints of ring-closing metathesis. Treatment of diene 283 with 10 mol % of 4 in dichloromethane provided the corresponding tricyclic system 284 in 71% yield as a single diastereomer. The authors noted that only one isomer underwent ring-closing metathesis, presumably due to conformational constraints.

AcO,

CH2CI2

71%

283

284

MeOv

kempane

A ring-closing metathesis strategy was employed by Burnell and Zhao in their synthesis of the tetracyclic core of several kempane derivatives. 137 Kempanes are a group of complex tetracyclic diterpenes that

Chapter 5 Large-Ring Carbocycles

541

serve as key defense molecules for many species of termites. The tetracyclic core, incorporating seven contiguous stereocenters, is especially challenging from a synthetic stand point. Most notably, the generation of the cycloheptene ring proved to be a considerable challenge in a previous synthesis of this compound.13 Ring-closing metathesis of diene 285 with 3 mol % of 4 in deuterated benzene was moderately successful in generating the cycloheptene ring, and subsequently the corresponding tetracycle 286 in 52% yield. Several spirocyclic compounds incorporating seven-membered rings have also been prepared by ring-closing metathesis. These molecules are important structural motifs that are found in a number of natural and unnatural products. A number of examples are illustrated in the paragraphs below. Brimble and Trzoss used a double-alkylation/ring-closing metathesis approach in their synthesis of spiroimines containing seven-membered ring carbocycles.106 Lactams 287, 289, and 291 were subjected to ring-closing metathesis using 5 mol% of 3 in dichloromethane to provide the corresponding 5,7-(288), 6,7-(290) and 7,7-(292) spirolactams in upward of 90% yield. It is interesting that the yields of seven-membered ring spirolactams are higher than the analogous six-membered ring spirolactams, presumably due to the greater flexibility of the diene precursors for the seven-membered rings.

\

n

CH2CI2 rt, 3 h

t

l

//

288, n = 1 93% 290, n = 2 95% 292, n = 3 92%

287, n = 1 289,n = 2 291, n = 3

*0

°Ύ HN

CH2CI2 reflux 90%

293

Hughes and co-workers applied their ring-closing metathesis strategy using zizane as a chiral auxiliary to the synthesis of enantiopure seven-

542

Name Reactions for Carbocyclic Ring Formations

membered ring spirocarbocycles.67 Diene precursor 293 required 5 mol % catalyst loading of 3 in refluxing dichloromethane to achieve a 90% yield of the desired spirocycle 294. The authors reported on the synthesis of several additional seven-membered ring spirocycles as part of this effort. Undheim and co-workers employed their olefin metathesis strategy for the synthesis of five- and six-membered ring spirocyclic carbocycles to prepare seven-membered ring spirocyclic carbocycles for use as templates in natural product synthesis.68 Reaction of diene 295 with 2 mol % of 3 furnished the corresponding spirocycle 296 in only 60% yield. However when diene 297 was reacted under similar conditions, the desired spirocycle 298 was obtained in 90% yield. Although no specific reason is given for the lower yield of 296, it is possible that conformational constraints and/or sterics may have played a role. N-/OCH3 PhHorPh rt or reflux 60%

N-.OCH3 PhHorPh rt or reflux 90%

Singh and co-workers applied their methodology for the synthesis of embellished spiro-fused bicyclo[2.2.2]octane systems to the synthesis of seven-membered ring carbocyclic derivatives.139 Treatment of diene 299 with 10 mol % of 3 in dichloromethane gave the corresponding spirocyclic carbocycle 300 in 86% yield.

CH2CI2 rt, 5 h 86%

299

"ΌΗ 300

Chapter 5 Large-Ring Carbocycles

543

Bennasar and co-workers used ring-closing metathesis to prepare 2,3fused indole derivatives, which are prominent heterocyclic components of a number of natural products such as ervitsine.140 Treatment of dienes and 301 and 303 with 10 mol % 3 in refluxing dichloromethane gave the corresponding cyclohepat[6]indoles 302 and 304 in 65 and 60% yields, respectively. The modest yields in these examples were likely do to conformational constraints.

Chattopadhyay and co-workers applied an olefin metathesis strategy in the preparation of a carbocyclic naphthalene derivative containing a sevenmembered ring carbocycle with the goal of generating cycloheptanaphthalene, an important enzyme inhibitor.141 Reaction of diene 305, prepared in two steps from commercially available 2,7dihydronaphthalene using a double Claisen rearrangement/acetylation sequence (not shown), with 5 mol % 3 in dichloromethane produced the corresponding tricyclic system 306 in 79% yield.

Name Reactions for Carbocyclic Ring Formations

544

AcO

OAc

CH2CI2 rt, 8 h

AcO

OAc

79%

305

H0 2 C

306

C0 2 H

cyclohepta naphthalene inhibitor

Eight-Membered Rings The synthesis of cycloctonoids using ring-closing metathesis was first addressed by Grubbs and co-workers in 1995.142 Their initial studies revealed that intermolecular cross-metathesis was favored over the intramolecular ring-closing process. This problem was eventually solved by building conformational constraints into the diene precursors such that preorganization favors ring-closing metathesis. For example, \,2-transdisubstituted cyclohexane derivative 307, when treated with 5 mol % of 2 in benzene, gave the corresponding fused bicyco[6.4.0]dodecane derivative 308 in 75% yield after only 4 hours. In contrast, treatment of the cw-cyclohexane precursor 309 under similar reaction conditions gave only 33% yield of the desired product 310, and a number of side products, highlighting the importance of conformational constrains in ring-closing metathesis. OTES

OlES// PhH rt, 4 h 75%

PhH rt, 20 h 33%

Chapter 5 Large-Ring Carbocycles

545

More recently, Percy and co-workers used a ring-closing metathesis approach to synthesize highly functionalized difluorinated cylooctenones.14 These compounds have been used in the design and synthesis of protease inhibitors, as they have been shown to be effective transition-state mimetics. In addition, the electrophilic nature of the ring system makes them attractive targets for adduct formation with active site nucleophiles such as serine. Reaction of allyl alcohol 311 with or without (not shown) the presence of Ti(Oz'-Pr)4 as a precatalyst and 5 mol % of 3 failed to provide the corresponding cyclooctenol 312. However, when ß-hydroxy ketone 313 was used instead, the corresponding difluorinated cyclooctenone 314 was produced in 78% yield. The authors later reported a shorter route to a similar difluorinated system using the same ring-closing metathesis approach (not shown). Unfortunately, the substrate required longer reaction times (166 h) and gave lower yields. OH F

OH F

3, Ti(0;-Pr) 4 GH2CI2 reflux, 24 h NR

311 OH F

O F 313

OBz O

312 3, Ti(0/-Pr) 4 CH2CI2 reflux, 24 h 78%

314

TX OBz

4, Ti(0/-Pr) 4 OH2CI2 reflux

315, R = H 317, R =

&

316, R: H 24% 318, R:

57%

Percy and co-workers applied a similar strategy in the synthesis of a trisubstituted cyclooctene derivative in an effort to determine the limits of relay ring-closing metathesis.144 Reaction of diene 315 (R = H) in the presence of 4 (three additions: 10 mol %, then 5 mol % then 5 mol % over a 12-day period) and Ti(0/-Pr)4 in refluxing dichloromethane furnished the corresponding octocycle 316 in only 24% yield. However, when a relay approach was employed, diene 317 (R = (CH2)3CHCH3) gave the

Name Reactions for Carbocyclic Ring Formations

546

corresponding cyclooctene 318 in 57% yield, a marked improvement over the previous synthesis. Paley and co-workers used enantiopure r|4-(l-sulfinyldiene)iron(0) tricarbonyl complexes as templates for the enantioselective construction of eight-membered ring carbocycles.117 Enantiopure homoallyl alcohol adducts 319 and 321, when treated with 8 mol % of 3 in toluene, gave the corresponding octocycles 320 and 322 as single diasteromers in 87 and 89% yield, respectively.

OR

PhCH 3

°Fe(CO)3

O Fe(CO)3 H3CO

H3CO R=MOM

R=MOM

320, (7S) 87% 322, (7R) 89%

319, (7S) 321, (7R)

Porco and co-workers used a diversity oriented/ring-closing metathesis approach to construct several complex systems as small molecule protein modulators.145 Microwave irradiation of Michael adduct 323 in the presence of a catalytic amount of 4 in refluxing dichloromethane gave the corresponding cyclooctene derivative 324 in modest yield. The authors included several additional examples as part of their report. C02CH3 ' -CO2CH3

323

H 3 C0 2 C

150\Λ/μνν CH2CI2 reflux 68%

324

Hanna and Ricard prepared several eight-membered ring carbocyclic rings from methyl 6-deoxy-6-iodo-3,4-isopropylidene-2-0-(teributyldimethyl-silyl)-D-galactopyranoside and methyl 6-deoxy-6-iodol,2:3,4-di-0-isopropylidene-D-galactopyranoside using a ring-closing metathesis strategy.1 ' Diene 325, prepared in two steps from methyl 6deoxy-6-iodo-1,2:3,4-di-0-isopropylidene-D-galactopyranoside, gave the

Chapter 5 Large-Ring Carbocycles

547

corresponding cyclooctene derivative 326 in 94% yield when treated with 5 mol % 3 in refluxing dichloromethane. Several derivatives with various protecting groups were also reported, and the authors applied this strategy to construct a number of carbohydrate-based cyclooctanoids in a later report (not shown).146

CH2CI2 reflux, 2 h 94%

Le Merrer and co-workers employed a ring-closing metathesis strategy to access a number of polyfunctionalized cyclooctane carbasugars as part of their ongoing effort to prepare new glycosidase inhibitors and noninsulino-based compounds for the treatment of diabetes. Olefin metathesis of 327 using up to 13 mol % of 3 in dichloromethane gave the corresponding c/s-cyclooctene product 328 in 87% yield.

CH2CI2 87%

HO/,,/

\VDH

O PhH reflux, 31 h 44%

Pff

Ό

ΑΪ

330

329 H OH

331

Λ ΟΟΗ 3

O

PhH reflux, 41 h 24%

A

Ptt v ^ 0

^ O .

ljV

332

.AOCH-,

548

Name Reactions for Carbocyclic Ring Formations

Holt and co-workers extended their ring-closing metathesis strategy for the synthesis of enantiomerically pure annulated six- and sevenmembered ring carbohydrate systems to systems containing containing eightmembered ring carbocycles. Treatment of 5-hydroxy-l,9-diene precursors 329 and 331 with a 9 mol % 3 in refluxing benzene provided the corresponding 6,6,8-c«-330 and trans-332 annulated systems in 44 and 24% yield, respectively. The authors noted that conformational constraints and the presence of the tertiary alcohol likely played a role in the successful transformation. In their continuing efforts to synthesize the carbocyclic core of sesquiterterpenes such as ophiobolin A, Wicha and co-workers constructed a 5,8-fused carbocyclic system.148 Reaction of 333 with 5 mol % of 4 in refluxing dichloromethane furnished the desired bicyclic system 334 in 95% overall yield. H CO2CH3

H3CO2Q j - | CH2CI2 reflux, 6 h 95% 333

H^C0 2 C

334

ophiobolin A

Martin and co-workers applied their ring-closing metathesis strategy to the synthesis of 5,6- and 5,7-fused butyrolactones to 5,8-fused butyrolactone systems.77 Diene precursor 335 was subjected to ring-closing metathesis using 10 mol % of 4 in refluxing dichloromethane to produce the corresponding α,β-fused γ-lactone 336 in 45% yield.

to O II

CH2CI2 reflux, 3 h 45% 335

C3H7

336

S02Ph

V

^

Chapter 5 Large-Ring Carbocycles

549

Krafft and co-workers used ring-closing metathesis to prepare several 'inside-outside' medium-size rings, including eight-membered carbocycles, as scaffolds for natural products synthesis. Reaction of bicyclic lactone 337 with 10 mol % of 4 in refluxing dichloromethane gave the corresponding tricyclic lactone 338 in 85% yield after only 2 hours. Additional eightmembered ring carbocycles incorporating functional handles were also reported, though significantly higher catalyst loadings (upward of 50 mol %) were required to achieve high yields. Attempts to apply this strategy to the synthesis of nine-membered ring carbocycles led solely to the production of dimeric products (not shown).

(+)-asteriscanolide

Paquette and co-workers employed a ring-closing metathesis strategy in their total synthesis of (+)-asteriscanolide.149 The sesquiterpenoid framework of (+)-asteriscanolide consists of a rather uncommon bicyclo[6.3.0]undecane ring system bridged by a butyrolactone fragment. Ringclosing metathesis of 5,5-diene precursor 339 using 10 mol % of 3 in refluxing dichloromethane proceeded smoothly to give the corresponding carbocyclic core (340) of (+)-asteriscanolide in 93% yield. The authors speculated that limited conformational flexibility of the diene substrate was critical to the high yields achieved in this transformation. Four additional steps were required to access (+)-asteriscanolide. Krafft and co-workers

550

Name Reactions for Carbocyclic Ring Formations

applied a similar ring-closing metathesis strategy in their 2001 synthesis of (+)-asteriscanolide (not shown).150 Tadoano and co-workers used olefin metathesis as a key step in their synthesis of (±)-mycoepoxydiene, a novel octacycle with an oxygen-bridged[4.2.1]nona-2,4-diene core.151 Reaction of diene 341 with 20 mol % of 3 in refluxing benzene furnished the corresponding oxygen-bridged cyclooctene derivative 342 in 83% yield. The authors noted that a highly dilute solution was essential in obtaining high yields of the desired product. OTBDPS

OTBDPS PhH reflux 83% 342

mycoepoxydiene

Mascarenas and co-workers employed a similar strategy in their synthesis of eight-membered ring carbacycles using a ring-closing metathesis/ring fragmentation strategy.152 Treatment of 343 as a mixture of diasteromers with 5 mol % of 3 in refluxing dichloromethane provided the desired bridged bicyclic compound 344 as the only product in 15% yield. The unreactive trans-isomer was easily separated from the bicyclic system after deprotection of the silyl ether. Further studies showed that enantiopure alcohol 345 underwent ring-closing metathesis using 5 mol % 3 in dichloromethane at room temperature in only nine hours to give the corresponding bicylic system 346 in 95% yield. Treatment with lead acetate led to the production of the corresponding cycloctanoid in near quantitative yields (not shown).

OTBS 343

CH2CI2 reflux, 12 h 15%

344

OTBS

Chapter 5 Large-Ring Carbocycles

OH 345

551

CH2CI2 rt, 9 h

95%

346

Rodriguez and co-workers applied a similar strategy in the synthesis bicyclo[4.2.1]nonane derivatives as precursors to functionalized cyclooctanes.153 Reaction of ketones 347, 349 and 351 in refluxing dichloromethane with 2 mol % of 4 gave the corresponding cyclooctene derivatives in 68-74% yield. Unfortunately, these transformations required long reactions times and the modest yields observed with substrates 350 and 352 were presumably due to sterics and catalyst decomposition. On the other hand, treatment of alcohols 353 and 355 using only 1 mol % of 4 in refluxing dichloromethane furnished the corresponding carbocycles in high yields (9298%) in only two to three hours.

CH2CI2 reflux

347, R1 = H, R2 = H 1

348, R1 = H, R2 = H 84%

2

349, R = CH 3 , R H 1 :2 _ 351, R = H , R CH 3

350, R1 = CH 3 , R2 = H 70% 352, R1 = H, R2 = CH 3 68%

CH2CI2 reflux

353, R1 = H, R2 = H 1

2

355, R = H, R = CH 3

C0 2 CH 3

C0 2 CH 3 354, R1 = H, R2 = H 92% 356, R1 = H, R2 = CH 3 98%

Singh and co-workers used Rodriquez's ring-closing metathesis strategy in the stereoselective synthesis of several expanded homologs of the cucumin family.154 These compounds exhibit cytotoxic and antibacterial properties. Diquinane derivative 357 underwent ring-closing metathesis in

552

Name Reactions for Carbocyclic Ring Formations

the presence of 4 in dichloromethane in under an hour to provide the corresponding tricyclic carbocycle 358 in modest yield.

Chapter 5 Large-Ring Carbocycles

553

Paquette and Efremov used a ring-closing metathesis strategy in their first total synthesis of the rearranged neo-clerodanes, teubrevin G and teubrevin H.155 These compounds feature a cycloctanene core fused and spiroannulated to smaller oxygen containing rings. Treatment of triethylsilyl ether 359 with 30-35 mol % of 3 in refluxing dichloromethane for one week furnished the corresponding fused octocycle 360 in 53% yield. Olefin metathesis with enone 361 under similar reaction conditions gave only 35% yield of the desired product 362. However, reaction of enone 361 with 10 mol% of 4 in refluxing dichlromethane gave the desired product in 90% yield after 34 hours. Prunet and co-workers employed ring-closing metathesis as a key step in their synthesis of the BC bicycle of Taxol, a potent treatment for breast and ovarian cancer. Previous research showed that dienes 363 and 365, when treated with 10 mol % of 3 in refluxing benzene or 5 mol % of 5 in refluxing 1,2-dichloroethane, gave the corresponding C9-C10 cyclooctene derivatives in good yield.156 However, in an effort to prepare the C10-C11 cyclooctene system using the same strategy, the authors observed that only diene 367 underwent ring-closing metathesis suggesting a higher energy barrier to preorganzation for these substrates.157 The authors went on to demonstrate that catalysts 3 (30 mol %), 4 (10 mol%), and 5 (5 mol %) could be successfully employed to produce the desired C10-C11 cyclooctene system (not shown) in modest yields (65%, 69%, and 72% yield, respectively).

1,2-DCE reflux, 12 h

1,2-DCE reflux, 12 h

365

366

554

Name Reactions for Carbocyclic Ring Formations

3, 4, or 5 1,2-DCE 65-72%

367

368 OHC)

Taxol

Granja and co-workers employed a ring-closing metathesis strategy in their synthesis of a novel steroid-like polycycle incorporating a 6,8,6-fused carbocyclic system.158 These molecules purportedly mimic the putative transition state structure of the isomerization reaction of previtamin D3 to vitamin D3. Treatment of diene 369 with near quantitative amounts of 3 in refluxing dichloromethane gave the desired tricyclic system 370 as a mixture of diastereomers in 95% yield after 6 days. In a later report, several additional examples bearing various substitutions patterns were reported (not shown).159

CH2CI2 reflux, 6 d 95%

TBSO

369

TBSO

370

Singh and co-workers also applied their methodology for the synthesis of embellished spiro-fused bicyclo[2.2.2]octane systems to the synthesis of eight-membered ring carbocyclic derivatives.1 Treatment of diene 371 with 5 mol % of 4 in dichloromethane gave the corresponding spirocyclic carbocycle 372 in 89% yield.

Chapter 5 Large-Ring Carbocycles

555

GH2CI2 rt, 0.5 h 89% 372

371

Bennasar and co-workers used their ring-closing metathesis strategy for the formation of 2,3-fused indole derivatives containing seven-membered ring cabocycles to prepare 2,3-fused indole derivatives containing eightmembered ring carbocycles.161 Treatment of diene 373 with 10 mol % 3 in refluxing dichloromethane furnished the corresponding cyclooctindole derivative 374 in 85% yield.

-S02Ph

373

CH2CI2 reflux, 12 h 85%

~S0 2 Ph

374

Large-Membered Rings Several large-membered ring systems have been synthesized using ringclosing metathesis. This section is organized by ring size and highlights a number of examples including nine-, ten-, eleven-, twelve-, thirteen-, fifteen-, and sixteen-membered ring carbocycles. Paley and co-workers used enantiopure r|4-(l-sulfinyldiene)iron(0) tricarbonyl complexes as templates for the enantioselective construction of nine-membered ring carbocycles, in addition to seven- and eight- membered ring carbocycles.117 Enantiopure homoallyl alcohol adduci 375, when treated with 8 mol % of 3 in toluene, gave the corresponding nine-membered carbocyclic ring in 88% yield with a cisltrans ratio of 35:1.

556

Name Reactions for Carbocyclic Ring Formations

.OMOM

O Fe(CO)3

PhCH3 88%

H3CO R = MOM

R = MOM

375

376

Holt and co-workers applied their ring-closing metathesis strategy for the synthesis of six-, seven-, and eight-membered ring annulated carbohydrate systems to synthesize a number of enantiomerically pure annulated carbohydrate systems containing nine-membered ring carbocycles.90 Treatment of cw-diene 377 with a catalytic amount of 3 in refluxing benzene gave the corresponding 6,6,9-carbocycle 378 in 52% yield. However, treatment of the trans-diene 379 under similar conditions gave none of the desired product, highlighting the importance of conformational constraints on nine-membered ring systems. *OCH 3 OH

PhH reflux, 17 h 52% 378

PhH reflux, 17 h NR

<X ,*OCH 3 OH

380

Clark and co-workers162 used the olefin metathesis strategy pioneered by Rodriquez and co-workers for the synthesis of eight and nine-membered ring carbocycles, in their synthesis of the nine-membered carbocyclic core of a class of herbicidial nonadrides known as the cornextins. Treatment of diene 381 with either catalytic 3 in refluxing dichloromethane, or 4 in

Chapter 5 Large-Ring Carbocycles

557

toluene, produced the desired nine-membered ring carbocycle 382 in 70% and 61% yield, respectively as mixtures of diastereomers. In a later report, Clark and co-workers employed a ring-closing fragmentation strategy complete the synthesis of (±)-5-ep/-hydroxycornexistin (not shown).164 3, CH2CI2 reflux, 60 h 70% or 4, PhCH 3 reflux, 3 h 61% H(X

HQ

hydroxycornexistin

cornexistin

384

ingenol

Wood and co-workers employed a ring-closing metathesis strategy in their construction of the carbocyclic core of ingenol.165 Ingenol esters have been shown to mimic diacylglycerol and function as PKC activators. These compounds are particularly challenging from a synthetic stand point due to their high degree of oxygenation, including a c/s-triol and highly strained inside-outside BC ring system. Treatment of diene 383 in refluxing toluene with four additions of 20 mol % of 3 every 45 minutes led to the construction

558

Name Reactions for Carbocyclic Ring Formations

of the desired inside-outside ring system 384 in 45% yield. The research groups of Winkler166 and and Kigoshi167 have independently applied similar strategies in their syntheses of ingenol (not shown). e«i-Clavilactone B, a unique compound with antifungal and antibacterial properties, was synthesized by Barrett and co-workers using olefin metathesis as a key step in their strategy.168 Extensive optimization led to the slow addition of 40 mol % of 4 to diene 385 in the presence of 80 mol % tetrafluorobenzoquinone in toluene to afford the desired 10-membered ring 386 in 65% yield. The authors noted that the reaction proceeded smoothly without affecting the strained epoxide ring. Treatment of 386 with CAN (not shown) furnished the desired target.

TFBQ (80 mol%) OCH 3 -

s-0

PhCH 3 , 80 °C 65%

»

386

385

eni-clavilactone B

Gennari and co-workers employed a ring-closing metathesis strategy in their synthesis of C-7 substituted eleuthesides.169 These molecules are analogs of the sarcodictyin family, which have shown significant microtubule stabilizing activity in tumor cell lines, in addition to the ability to inhibit Taxol resistant tumor cell lines. Dienes 387 and 389 were subjected to ringclosing metathesis using 6 mol % of 4 in dichloromethane, first at room temperature and then at reflux, to provide the corresponding Z-alkenes 388 and 390 in 78% and 71% yields, respectively. A number of additional alkenes bearing various functional handles were also synthesized.

Chapter 5 Large-Ring Carbocycles

559 OMOM

OAc 387

CH2CI2, rt 16 h, then reflux 7h, 78% (Z) OMOM

OMOM CH2CI2, rt 16 h, then reflux 7h,

71% (Z)

390

389

N^NCH3

eleutherobin

O I

OAc

«

<

OH OH

1,4-benzoquinone (20%) ^. PhCH3 reflux

TBSO

OTBS

392, 3S 40% 393, 3R 31%

391

"Ό diversifolin

Kobayashi and co-workers employed an olefin metathesis strategy in their synthesis of the ll-oxabicyclo[6.2.1]undec-3-ene core of diversifolin, a

560

Name Reactions for Carbocyclic Ring Formations

densely oxygenated germacrane-type sesquiterpene with the ability to inhibit transcription factor NF-kB.170 Reaction of 391 as a mixture of diasteromers with 20 mol% of 4 in the presence of 20 mol % of 1,4-benzoquinone in refluxing toluene gave the desired bicyclic lactones 3S-(392) and 3i?-(393) in 71% overall yield. It is interesting that when only 10 mol % of 4 was used without 1,4-benzoquinone, only the 37? isomer 393 was obtained (27% yield) in addition to a trace amount of the 3S isomer, recovered starting material, and an isomerisation product (not shown). The reactions were also attempted using 3 with no yield of the desired products.

1,4-benzoquinone (40 mol%)

fc-

CH2CI2 reflux, 1 h

14%

394

CH2CI2 reflux, 1 h 78%

396 HO

Λ

3 CH2CI2 reflux, 1 h 85%

OH

398

399

Chapter 5 Large-Ring Carbocycles

561

abyssomicin C

Nicolaou and Harrison used a ring-closing metathesis strategy to construct the carbocyclic core of abyssomicin C, one of the only compounds to exhibit antibiotic activity via inhibition of the /?-aminobenzoic acid biosynthetic pathway.171 The larger, strained 11-membered ring containing four stereogenic centers presented some specific challenges. Treatment of vinyl ketone 394 with 10 mol % of 4 and 20 mol % of 1,4-benzoquinone in refluxing dichloromethane gave the desired product, abyssomicin C 395 in only 14% yield. However, when a diastereomeric mixture of vinylic triol 396 was treated with 5 mol % of 4 in refluxing dichloromethane, the corresponding carbocyclic core 397 was generated in 78% yield. Unfortunately, the authors were unable to find a suitable oxidation strategy to produce abyssomicin C. Speculation that the two additional sp2 centers of 394 were responsible for the modest conversion of 394 to 395, in addition to difficulties in oxidizing 397 led to the design of 398, which was devoid of the intramolecular hemiketalization problem. This substrate smoothly underwent ring-closing metathesis using 5 mol % of 4 in refluxing dichoromethane to provide the desired carbocycle 399 in 85% yield. 399 could be readily oxidized and deprotected to afford the desired product (not shown).

clavirolide C

Name Reactions for Carbocyclic Ring Formations

562

Hoyveda and Brown used olefin metathesis to synthesize clavirolide The transC, a member of the dolabellane family of diterpenes.17 bicyclo[9.3.0]tetradecane architecture of clavirolide C presents an interesting synthetic challenge. Reaction of diene 400 in the presence of 10 mol % of 6 in refluxing dichloroethane gave the corresponding carbocyclic macrocycle 401 in 70% yield with greater than 95% trans selectivity. The authors noted that their attempts to employ catalyst 4 led to less than 10% conversion to the desired macrocycle. In addition, ring-closing metathesis using either the free allylic alcohol or corresponding ketone led to complex mixtures of products (not shown). Botta and co-workers employed a ring-closing metathesis strategy in the stereoselective synthesis of advanced intermediates in route to the total 1 71

synthesis of taxuspines U and X, the biogenic precursors for Taxol. In addition to an interesting and synthetically challenging architecture, taxuspines U and X are believed to have similar microtubule stabilizing properties to Taxol, and as such are of current interest for their medicinal properties. Ring-closing metathesis with 402 in the presence of either 3 or 4 using a number of reaction conditions failed to provide the desired 3,8secotaxane diterpenoid 403. The authors speculated that the failed ringclosing metathesis was the result the catalyst complexing with the more electron-rich alkyne in the presence of the electron rich OTBDPS group. Reduction of the alkyne to the alkene (not shown) and subsequent treatment of the corresponding co-co'-diolefin 404 with 10 mol % of 4 gave the corresponding 3,8-secotaxane diterpenoid 405 in 20% yield. In a later report, Botta and co-workers were finally able to achieve cyclization with a number of alkynyl substrates using 20 mol % 1 in toluene in low yeild (20% yeild). 174 This led the authors to speculate that the molecular constraints for cyclization when the alkyne is present may require too high of energy barrier for ring-closing metathesis to occur. OAc

OAc

/ = ό — "Ί

\

/ ^ i^l ^ 1 " " ^ 1 1 ÖTBDPS 402

3or4 various conditions NR

OTBDPS1 403

Chapter 5 Large-Ring Carbocycles

OAc

563 OAc

OAc

CH2CI2 rt, 36 h 20%

OTBDPS

OTBDPS1 405

404 OAc

OAc

OAc

OAc

OAc

AcO"

OAc taxuspine U

OAc OAc

taxuspine X R = frans-cinnamoyl

Blechert and co-workers used ring-closing metathesis to synthesize the central bridged bicyclo[5.3.1]undecane moiety of Taxol.175 Diene precursor 406, prepared in nine steps from commercially available (-)-ßpinene, was subjected to ring-closing metathesis using 10 mol % of 3 in refluxing dichloromethane to give 58% of the desired product (407) in four hours. The authors noted that only one vinyl acetate cyclized to form the desired macrocycle, presumably due to the sterics of the bridgehead. OAc AcO

-',/·^.

CH2CI2 reflux, 4 h 59%

406

Deslongchamps and co-workers approach to the synthesis of Kempane diterpenes employed a ring-closing metathesis strategy in the construction of the 13-membered ring carbocycle, which was subsequently subjected to a transannular Diels-Alder reaction to produce the tricyclic core.176 Treatment of tetraene ester 408 with 6 in refluxing toluene gave the corresponding triene 409 with a trans-cis-cis geometry as the only product in 74% yield.

Name Reactions for Carbocyclic Ring Formations

564 HO.

6 PhCH 3 reflux 74%

C0 2 Me C0 2 Me

409

408

(±)-kempane

A number of ring-closing metathesis strategies have been employed in the the 13-membered core of roseophilin, a novel antitumor antibiotic with a unique pentacyclic skeleton. The first synthesis by Fuchs and co-workers employed diene 410 as a mixture of diasteromers.177 Treatment of 410 with 30 mol % of 3 in refluxing dichloromethane gave the corresponding ansabridged silylether 411 as a single diastereomer in 60% yield. The modest yield was attributed the conformationally biased diene precursor. The 178

17Q

1 SO

research groups of Fürstner, Hiemstra, and Boger used a similar approach in their syntheses of roseophilin in 1999, 2000, and 2001, respectively, although notably Boger achieved an 88% yield of the ansabridged macrocycle as a 1:1 mixture of the the E and Z isomers using a triene analog of 410 (not shown). OTIPS OTIPS

CH2CI2 reflux, 25 h 60%

411 O

Tius and co-workers also used a ring-closing methathesis strategy in their construction of the macrocyclic ring of roseophilin.181 Treatement of the more conformationally flexible olefin 412 with 30 mol % of 3 in refluxing dicholormethane gave the corresponding 13-membered ring carbocycle 413 in 90% yield.

Chapter 5 Large-Ring Carbocycles

565

BzO

BzO

CH2CI2 reflux 90% 413

enf-roseophilin

6 PhCH 3 80 °C

OBn

then 10% Pd/C, H 2 EtOAc, rt 80-85% (two steps)

OBn

(-)-okilactomycin

Smith and co-workers used a ring-closing metathesis strategy in their synthesis of the 13-membered ring of (-)-okilactomycin, a novel polyketide antitumor antibiotic.182 (-)-Okilactomycin is a considerable challenge synthetically due to its highly functionalized cyclohexene ring complete with a spirocenter and a 2,6-c/5-tetrahdyropyronone moiety. Ring-closing metathesis of lactone 414 in the presence of 30 mol % of 6 in toluene

566

Name Reactions for Carbocyclic Ring Formations

followed by catalytic hydrogenolysis, gave the corresponding c/s-alkene 415 in 80-85% yield over two steps. The authors noted that to achieve optimal yields and prevent dimerization, 6 was decomposed by air before concentration. A similar strategy was employed in their most recent report on (-)-okilactomycin (not shown).183 Nakata and co-workers recently employed a ring-closing metathesis strategy to construct the 14-membered carbocyclic core of methyl sarcophytoate, a biscembranoid.184 Olefin metathesis of diene 416 using a stoichiometric amount of 4 in refluxing benzene gave the corresponding macrocycle 417 in 43 % yield.

C02Me

C02Me

PhCH3 reflux, 0.5 h 43%

417

methyl sarcophytoate A ring-closing metathesis strategy was first employed by Furstner and 1 RS

co-workers in the synthesis of civetone, a macrocyclic musk. Treatment of diene 418 using 5 mol % of 2 in refluxing dichloromethane led to the corresponding 15-member ring macrocycle 419 in 72% yield with an E.Z selectivity of 4.6 to 1.

418

CH2CI2 reflux, 24 h 72% £:Z = 4.6:1

419

civetone

Chapter 5 Large-Ring Carbocycles

567

Hagiwara and co-workers employed a similar metathesis strategy in Treatment of their synthesis of (7?)-(-)-muscone from (+)-citronellal.1 ketone 420, generated in seven steps from commercially available (+)citronellal, with 5 mol % of 3 furnished the corresponding 15-membered ring carbocycle 421 in 78% yield as a mixture of E and Z isomers. Hydrogenation of 421 led to the final desired product (7?)-(-)-muscone (not shown). A similar protocol was employed in a recent synthesis by the same group.

187

(R)-(-)-muscone

Trost and co-workers used ring-closing metathesis in their total synthesis of (-)-terpestacin.188 Terpetacin is a known inhibitor of syncytia, produced by HIV infected cells, and has also been shown to inhibit angiogenesis. Treatment of 422 with 10 mol % of 4 in benzene gave the corresponding 15-membered ring carbocycle 423 in 35^45% yields. The authors noted that temperature and the presence of the allylic alcohol were critical in the chemoselectivity of the ring-closing metathesis.

568

Name Reactions for Carbocyclic Ring Formations

terpestacin

OH

Collins and co-workers used relay ring-closing metathesis to synthesize the macrocyclic component of longithorone C, a farnesylated 1 SQ

quinone with a macrocyclic [12]paracyclophane skeleton. Reaction of ester 424 with 10 mol % of a 4 provided the corresponding macrocycle 425 in 68% yield, based on recovery of starting material. Collins recently expanded on this work using catalyst 8 to provide comparable yields (not shown).190 Several other groups including Smith,191 Kotha192 and Suzuki193 have also employed ring-closing metathesis strategies in the synthesis of related cyclophane derivatives (not shown).

ArO.

CH2CI2 reflux, 15 h 65% 424, Ar=3,5-bis(CF3)Ph

ArO 0 425, Ar=3,5-bis(CF3)Ph

longithorne C

Smith and co-workers recently used a Petasis-Ferrier rearrangement/ ring-closing metathesis to construct the 18-membered ring macrocyclic core of (-)-kendomycin, a polyketide macrocyclic endothelin receptor antagonist and anti-osteoporotic. 94 Reaction of diene 426, with 10 mol % of 4 in refluxing dichloromethane provided macrocycle 427 in 57% yield as the Z isomer, rather than the desired E isomer. Despite obtaining the undesired stereioisomer, Smith's report is the first synthesis of an a-branched trisubstituted olefin in a a large macrocylic structure. Compound 427 was

Chapter 5 Large-Ring Carbocycles

569

cleverly converted to the E isomer in four steps, and three additional steps were required to reach the final product, (-)-kendomycin.

0 H

OCH,

CH2CI2 reflux 57% Z

erV TBSO

H3CO 426

H3CO 427

OH

5.3.6

(-)-kendomycin

Experimental

The following example, adapted from Grubbs original report on ring-closing metathesis is still considered the standard for most ring-closing metathesis reactions. 36 ter*-Butyl-(cyclopent-3-enyloxy)-dimethyl-silane

OTBS

16

PhH rt, 5h 85%

OTBS

17

Typical experimental procedure: The diene 16 (0.5 mmol) was added to a homogenous orange red solution of 2 (0.01 mmol) in dry PhH (15 mL, 0.001 M) under argon. The resulting mixture was stirred at 20 °C for 5 h, at which time TLC showed the reaction to be complete. The reaction mixture was

570

Name Reactions for Carbocyclic Ring Formations

quenched by exposure to air, concentrated, and purified by flash chromatography (0 to 6% diethyl ether/hexanes) to give a colorless oil. The following procedure, adapted from Percy and co-workers synthesis of difluorinated cyclooctenoids, is a useful method when Ti(Oz'-Pr)4 is to be used as a precatalyst. 2,2-Difluoro-3-hydroxy-7,7-dimethyl-cyclooct-4-enone143 OH

O

3, Ti(0/-Pr)4 CH2CI2 reflux, 24 h 78%

314

Diene (1.28 mmol), Ti(0/-Pr)4 (0.422 mmol), and catalyst (0.064 mmol) were dissolved in dried, degassed dichloromethane (512 mL). The solution was allowed to reflux under inert atmospheric conditions for 24 h or until complete as monitored by 19F NMR. The solvent was removed under reduced pressure and the residue was taken up in diethyl ether (5 mL), filtered and concentrated under reduced pressure. The residue was taken up in methanol (1 mL) then eluted through a Stratospheres DPE tube, eluting with methanol ( 5 x 2 mL). The solution was concentrated under reduced pressure to afford a brown oil, which was purified by flash chromatography (silica gel, 20% diethyl ether/hexane) to give the cycloctenone as colorless solid. 5.3.7 1. 2. 3. 4.

5. 6. 7. 8.

References Tsuji, J.; Hashiguch, S. Tetrahedron Lett. 1980, 21, 2955-2958. Villemin, D. Tetrahedron Lett. 1980,21, 1715-1718. Schrock, R. R.; Murdzek, J. S.; Bazan, G. C; Robbins, J.; DiMare, M.; O'Regan, M. J. Am Chem. Soc. 1990,112, 3875-3886. (a) Fu, G. C; Grubbs, R. H. J. Am. Chem. Soc.1992, 114, 5426-5427. (b) Fu, G. C; Grubbs, R. H. J. Am. Chem. Soc. 1992,114, 7324-7325. (e) Fu, G. C.; Nguyen, S. T. Grubbs, R. H. J. Am. Chem. Soc.1993, 115, 9856-9857. (d) Nguyen, S. T. Grubbs, R. H.; Ziller, J. W. J. Am. Chem. SOc.1993,115, 9858-9859 a) Adlhart, C; Hinderung, C; Baumann, H.; Chen, P. J. Am. Chem. Soc. 2000, 122, 8204-8214. (b) Sanford, M. S.; J. A. Love, J. A.; Grubbs, R. H. J. Am. Chem. Soc. 2001,123, 654-6554. (a) Cavallo, L. J. Am. Chem. Soc.2002,124, 8965-8973. (b) Adlhart, C; Chen, P. J. Am. Chem. Soc 2004, 126, 3496-3510. (c) Straub, B. F. Angew. Chem. 2005, 117, 6129-6132.; (d) Straub, B. F. Angew.Chem., Int. Ed. 2005, 44, 5974-5978 Romero, P. E.; Piers, W. E. J. Am. Chem. Soc. 2005,127, 5032-5033. Armstrong, S. K. J. Chem. Soc, Perkin Trans. 1 1998, 371-388.

Chapter 5 Large-Ring Carbocycles

9. 10. 11. 12. 13. 14. 15. 16. 17. 18. 19. 20. 21. 22.

23. 24. 25. 26. 27. 28. 29. 30. 31. 32.

571

[R] Illuminati, G.; Mandolin L. Ace. Chem. Res. 1981,14, 95-102. Maier, M. E. Angew. Chem., Int. Ed.2000, 39, 2073-2077. (a) Bruice, T. C ; Pandit, U. K. J. Am. Chem. Soc.1960, 82, 5958-5865. (b) Schleyer, P. V. R. J. Am. Chem. Soc. 1961, 83, 1368-1373. [R] Jung, M. E.; Puzzi, G. Chem. Rev. 2005, 105, 1735-1766, and references therein. Hoye, T. R.; Zhao, H. Org. Lett. 1999,1, 1123-1125. [R] For a recent review on the advances and limitation in ring-closing metathesis, see Conrad, K.; Fogg, D. E. Curr. Org. Chem. 2006,10, 185-202. Sanford, M. S.; Love, J. A.; Grubbs, R. H. J. Am. Chem. Soc. 2001, 123, 65436554. Adjiman, C. S.; Clarke, A. J.; Cooper, G.; Taylor, P. C. Chem. Comm. 2008, 28062808. [R] For a recent review on new developments in olefin metathesis catalysts see: Michrawska, A.; Greala, K. Pure Appi. Chem. 2008, 80, 34-43. (a) Dunne, A. M.; Mix, S.; Blechert, S. Tetrahedron Lett. 2003, 44, 2733-2736. (b) Buschmann, N.; Wakamatsu, H.; Blechert, S. Synlett 2004, 4, 667-670. Bieniek, M.; Michrowska, A.; Gulajski, L.; Grela, K. Organometallics 2007, 26, 1096-1099. Stewart, I. C ; Ung, T.; Petnev, A. A.; Berlin, J. M.; Grubbs, R. H.; Schrodi, Y. Org. Lett. 2007, 9, 1589-1592. Hoye, T. R.; Jeffrey, C. S.; Tennakoon, M. A.; Wang, J.; Zhao, H. J. Am. Chem. Soc. 2004,726, 10210-10211. (a) Mohr, B.; Lynn, D. M.; Grubbs, R. H. Orgnaometallics 1995, 75, 4317^1325. (b) Krikland, T. A.; Lynn, D. M.; Mohr, B.; Grubbs, R. H. J. Org. Chem. 1998, 63, 9904-9909. (c) Lynn, D. M.; Mohr, B.; Grubbs, R. H.; Henling, L. M.; Day, M. W. J. Am. Chem. Soc. 2000, 122, 6601-6609. (d) Lynn, D. M.; Grubbs, R. H. J. Am. Chem. Soc. 2001,123, 3187-3193. Roberts, A. N.; Cochran, A. C ; Rankin, D. A.; Lowe, A. B.; Schanz, H-J. Organometallics 2007, 26, 6515-6518. Gallivan, J. P.; Jorda, J. P.; Grubbs, R. H. Tetrahedron Lett. 2005, 46, 2577-2580. Hong, S. H.; Grubbs, R. H. J. Am. Chem. Soc. 2006,128, 3508-3509. Jordan, J. P.; Grubbs, R. H. Angew. Chem., Int. Ed. 2007, 46, 5152-5155. (a) Michrowska, A.; Gulajski, L.; Kaczmarska, Z.; Mennecke, k.; Krischning, A.; Grela, K. Green Chem. 2006, 8, 685-688. (b) Rix, D.; Clavier, H.; Gulajski, L.; Grela, K.; Mauduit, M. Chem. Comm. 2007, 3771-3773. Clavier, H.; Grela, K.; Kirschning, A. Mauduit, M.: Nolan, S. P. Angew. Chem., Int. Ed. 2007, 46, 6786-6801. Binder, J. B.; Raines, R. T. Curr. Opin. Chem. Biol. 2008,12, 767-773. Keitz, B. K.; Grubbs, R. H. Organometallics ASAP. [R] For a recent review on sustainable concept in olefin metathesis, see Clavier, H.; Grela, K.; Krisching, A.; Mauduit, M.; and Nolan, S. P. Angew. Chem., Int. Ed. 2007,46,6786-6801. For representative examples, see (a) Maynard, H. D.; Grubbs, R. H. Tetrahedron Lett. 1999, 40, 4137^1140. (b) Ahn, Y. M.; Yang, K.-L.; Georg, G. I. Org. Lett. 2001, 3, 1411-1413. (c) Cho, J. H.; Kim, B. M. Org. Lett. 2003, 5, 531-533. (d) Nicola, T.; Brenner, M.; Donsbach, K.; Kreye, P. Org. Process Res. Dev. 2005, 9, 513-515. (e) Yee, N. K.; Farina, V.; Houpis, I. N.; Haddad, N.; Frutos, R. P.; Gallou, F.; Wang, X.-J.; Wei, X.; Simpson, R. D.; Feng, X.; Fuchs, V.; Xu, Y.; Tan, J.; Zhang, L.; Xu, J.; Smith-Keenan, L. L.; Vitous, J.; Ridges, M. D.; Spinelli, E. M.; Johnson, M.; Donsbach, K.; Nicola, T.; Brenner, M.; Winter, E.; Kreye, P.;

572

33.

34. 35. 36. 37. 38. 39. 40. 41. 42. 43. 44. 45. 46. 47. 48. 49. 50. 51. 52. 53. 54. 55. 56.

Name Reactions for Carbocyclic Ring Formations Samstag, W. J. Org. Chem. 2006, 71, 7133-7145. (f) Goldup, S. M.; Pilkington, C. J.; White, A. J. P.; Burton, A.; Barrett, A. J. M. /. Org. Chem. 2006, 71, 6185-6191. (g) Semeril, D.; Olivier-Bourbigou, H.; Bruneau, C; Dixneuf, P. H. Chem. Commun. 2002, 164-167. For representative examples see: (a) Schurer, S. C; Gessler, S.; Buschmann, N.; Blechert, S. Angew. Chem. 2000, 112, 4062^065. (b) Schurer, S. C; Gessler, S.; Buschmann, N.; Blechert, S. Angew. Chem., Int. Ed. 2000, 39, 3898-3901. (c) Mayr, M.; B. Mayr, B.; Buchmeiser, M. R. Angew. Chem. 2001, 113, 3957-3960. (d) Mayr, B.; Buchmeiser, M. R. Angew. Chem., Int. Ed. 2001, 40, 3839-3842. (e) Mayr, M.; Buchmeiser, M. R.; Wurst, K. Adv. Synth. Catal. 2002, 344, 712-719. (f) Pruhs, S.; Lehmann, C. W.; Furstner, A. Organometallics 2004, 23, 280-287. (g) Mayr, M.; Wang, D.; Kroll, R.; Schüler, N.; Pruhs, S.; Furstner, A.; Buchmeiser, M. R. Adv. Synth. Catal. 2005, 347, 484-492. (h) Gallivan, J. P.; Jordan, J. P.; Grubbs, R. H. Tetrahedron Lett. 2005, 46, 257-2580. (i) Hong, S. H.; Grubbs, R. H. J. Am. Chem. Soc. 2006, 128, 3508-3509. (j) Sußner, M.; Plenio, H. Angew. Chem. 2005, 117, 704-7048. (k) Sußner, M.; Plenio, H. Angew. Chem., Int. Ed. 2005, 44, 68856888. Allen, D. P.; Van Wingerden, M. M.; Grubbs, R. H. Org. Lett. 2009, 11, 12611264. Fu, G. C; Grubbs, R. H. J. Am. Chem. Soc. 1993,115, 3800-3801. Fu, G. C.; Nguyen, ST.; Grubbs, R. H. J. Am. Chem. Soc. 1993,115, 9856-9857. Okada, A.; Ohshima, T.; Shibasaki, M. Tetrahedron Lett. 2001, 42, 8023-8027. Aggarawa, V.; Daly, A. M. Chem. Comm. 2002, 2490-2491. Jung, M. E. Synlett 1999, 843-846. Heo, J.; Micalizio, G. C; Roush, W. R. Org. Lett. 2003, 5, 1693-1696. Parks, B. W.; Gilbertson, R. D.; Domaille, D. W.; Hutchison, J. E. J. Org. Chem. 2006, 71, 9622-9627. Chao, W.; Weinreb, S. M. Org. Lett. 2003, 5, 2505-2507. Kotha, S.; Sreenivasachary, N.; Mohanraja, K.; Durani, S. Bioorg. Med. Chem. Lett. 2001,11, 1421-1423. Undheim, K.; Efskind, J. Tetrahedron 2000, 56, 4847^857. Probst, N. P.; Haudrechy, A.; Pie, K. J. Org. Chem. 2008, 73,4339-4341. Gardiner, J.; Anderson, K. H.; Downard, A.; Abell, A. J. Org. Chem. 2004, 69, 3375-3382. Chippindale, A. M.; Davies, S. G.; Iwamoto, K.; Parkin, R. M.; Smethurst, C. A. P.; Smith, A. D.; Rodriquez-Solla, H. Tetrahedron 2003, 59, 3253-3265. [R] For recent reviews see: (a) Madsen, R. Eur. J. Org. Chem. 2007, 399^15. (b) Plumet, J.; Gomez, A. M.; Lopez, J. C. Mini-Rev. Org. Chem. 2007, 4, 201-216. (c) Argrofoglio, L. A.; Nolan, S. P. Curr. Top. Med. Chem. 2005, 5, 1541-1558. Park, A.; Moon, H. R.; Kim, K. R.; Chun, M. W.; Jeong, L. S. Org. Biomol. Chem. 2006, 4,4065-4067. Liu, L. J.; Yoo, J. C; Hong, J. H. Nucleos. Nucleot. Nucl. Acids. 2008, 27, 1186— 1196. Li, H.; Yoo, J. C; Hong, J. H. Nucleos. Nucleot. Nucl. Acids. 2008,27, 1238-1249. [R] For a recent review see: Donohoe, T. J.; O'Riordan, T. J. C; Rosa, C. P. Angew. Chem., Int. Ed. 2009, 48, 1014-1017. Srikrishna, A.; Ravikumar, P. C. Tetrahedron 2006, 62, 9393-9402. Srikrishna, A.; Kumar, S. R.; Ravikumar, P. C. Synth. Comm. 2007, 37,4123-4140. Srikrishna, A.; Khan, I. A.; Babu, R. R.; Sajjanshetty, A. Tetrahedron 2007, 63, 12616-12620. Srikrishna, A.; Satyanarayana, G. Tetrahedron. 2006, 62, 2892-2900.

Chapter 5 Large-Ring Carbocycles

57. 58. 59. 60. 61. 62. 63. 64. 65. 66. 67. 68. 69. 70. 71. 72. 73. 74. 75. 76. 77. 78. 79. 80. 81. 82. 83. 84. 85. 86. 87. 88. 89.

573

Srikrishna, A.; Lakshmi, B. V.; Ravikumar, P. C. Tetrahedron Lett. 2006, 47, 1277— 1281. Kulkarni, M. G.; Davawala, S. I; Shinde, M. P; Dhondge, A. P.; Borhade, A. S.; Chavan, S. W.; Gaikwad, D. D. Tetrahedron Lett. 2006, 47, 3027-3029. Paquette, L. A.; Peng, X.; Yang, J.; Kang, H. J. Org. Chem. 2008, 73, 4548^558. Srikrishna, A.; Dethe, D.H. Tetrahedron Lett. 2003, 44, 7871-7820. Srikrishna, A.; Pardeshi, V. H.; Satyanarayan, G. Tetrahedron: Asymm. 2008, 19, 1984-1991. Srikrishna, A. ; Babu, R. R. Tetrahedron Lett. 2007, 48, 6916-6919. Majumdar, K. C ; Islam, R.; Rahaman, H.; Roy, B. Org. Biomol. Chem. 2006, 4, 2393-2398. Srikrishna, A.; Babu, R. R. Tetrahedron Lett. 2007, 48, 6916-6919. Gurjar, M. K.; Ravindranadh, S. V.; Sankar, K.; Karmakar, S.; Cherian, J.; Chorghade, S. Org. Biomol. Chem. 2003,1, 1366-1373. Hobson, S. J.; Marquez, R. Org. Biomol. Chem. 2006, 4, 3808-3814. Hughes, R. C.; Dvorak, C. A.; Meyers, A. I. J. Org. Chem. 2001, 66, 5545-5551. Roulland, E.; Monneret, C.; Florent, J. J. Org. Chem. 2002, 67, 4399^406. Ghosh, S.; Sinha, S.; Drew, M. G. B. Org. Let. 2006, 8, 3781-3784. Wang, C ; Rath, N. P.; Covey, D. F. Tetrahedron Lett. 2006, 47, 7837-7839. Ichikawa, Y.; Yamaoka, T.; Nakano, K.; Kotsuki, H. Org. Lett. 2007, 9, 29892992. Mehta, G.; Singh, S. R. Tetrahedron Lett. 2005, 46, 2079-2082. Srikrishna, A.; Beeraiah, B. Tetrahedron: Asymm. 2008,19, 884-890. Miller, J. F.; Termin, M.; Koch, K.; Piscopio, A. D. J. Org. Chem. 1998, 63, 31583159. Francias, A.; Bedel, O.; Picoul, W.; Meddour, A.; Courteiu, J.; Haudrechy, A. Tetrahedron: Asymm. 2005, 75, 1141-1155. Swift, M. D.; Donaldson, A.; Sutehrland, A. Tetrahedron Lett. 2009, 50, 32413244. (a) Rodriquez, C. M.; Ravelo, J. L.; Rodriquez, C. M. Org. Lett. 2004, 6, 25; (b) Ravelo, J. L.; Rodriguez, C. M.; Martin, B. S. J. Organomet. Chem. 2006, 691, 5326-5335. Gagnon, D.; Lauzon, S.; Godbout, C ; Spino, C. Org. Lett. 2005, 7,4769^1771. Lee, C.-L. K.; Ling, H. Y.; Loh, T.-P. J. Org. Chem. 2004, 69, 7787-7789. Gardiner, J.; Anderson, K. H.; Downard, A.; Abell, A. J. Org. Chem. 2004, 69, 3375-3382. Hyldtoft, L.; Madsen, R. J. Am. Chem. Soc. 2000,122, 8444-8452. Doddi, V. R.; Kumar, A.; Vankar, Y. D. Tetrahedron 2008, 64, 9117-9122. Verhelst, S. H. L.; Wennekes, T.; van der Marel, G. A.; Overkleeft, H. S.; van Boeckel, C. A. A.; van Boom, J. H. Tetrahedron 2004, 60, 2813-2822. Totokotsopouos, S. M.; Koubis, A. E.; Gallos, J. K. Tetrahedron 2008, 64, 39984003. Kumaraswamy, G.; Sadaiah, K.; Ramakrishna, D. S.; Police, N.; Sridhar, B.; Bharatam, J. Chem. Comm. 2008, 5324-5326. Cumpstey, I.; Gehrke, S.; Erfan, S.; Cribiu, R. Carbohydr. Res. 2008, 343, 16751692. Ramstadius, C ; Hekmat, O.; Eriksson, L.; Stalbrand, H.; Cumpstey, I. Tetrahedron: Asymm. 2009, 20, 795-807. Whalen, L. J.; Halcomb, R. L. Org. Lett. 2004, 6, 3221-3224. Holt, D. J.; Barker, W. D.; Jenkins, P. R.; Davies, D. L.; Garratt, S.; Fawcett, J.; Russell, D. R.; Ghosh, S. Angew. Chem., Int. Ed. 1998, 37, 3298-3300.

574 90. 91. 92. 93. 94. 95. 96. 97. 98. 99. 100. 101. 102. 103. 104. 105. 106. 107. 108. 109. 110. 111. 112. 113. 114. 115. 116. 117. 118. 119. 120. 121. 122. 123. 124. 125.

Name Reactions for Carbocyclic Ring Formations

Holt, D. J.; Barker, W. D.; Jenkins, P. R. J. Org. Chem. 2000, 65,482^93. Kireev, A. S.; Nadein, O. N.; Agustin, V. J.; Bush, N. E.; Evidente, A.; Manpadi, M.; Ogasawara, M. A.; Rastogi, S. K.; Rogelj. S.; Shors, S. T.; Kornienko, A. J. Org. Chem. 2006, 71, 5694-5707. Srikrishna, A.; Satayanarayana, G.; Prasad, K. R. Syn. Commun. 2007, 37, 1511— 1516. Levine, S. R.; Krout, M. R.; Stoltz, B. M. Org. Lett. 2009,77, 289-292. Matovic, R.; Ivkovic, A.; Manojlovic, M.; Tokic-Vujosevic, Z.; Saicic, R. N. J. Org. Chem. 2006, 71, 9411-9419. Clive, D. J.; Liu, D. J. Org. Chem. 2002, 41, 2396-2398. Srikrishna, A.; Pardeshi, V. H.; Satyanarayana, G. Tetrahedron Lett. 2007, 48, 4087-4090. Srikrishna, A.; Beeraiah, B.; Gowri, B. V. Tetrahedron 2009, 65, 2649-2654. Song, Y.; Hwang, S.; Gong, P.; Kim, D.; Kim, S. Org. Lett. 2008, 70, 269-271. Trost, B. M.; Dogra, K. Org. Lett. 2007, 9, 861-863. Ciampini, M.; Perlmutter, P.; Watson, K. Tetrahedron: Asymm. 2007,18, 243-250. Lejkowski, M.; Banerjee, P.; Runskink, J.; Gals, H.-J. Org. Lett. 2008, 10, 27132716, White, D. E.; Stewart, I. C.; Grubbs, R. H.; Stoltz, B. M. J. Am. Chem. Soc. 2008, 750,810-811. Lee, M.; lee, T.; Kim, E.-Y.; Ko, H.; Kim, D.; Kim, S. Org. Lett. 2006, 8, 745-748. Simila, S. T. M.; Martin, S. F. J. Org. Chem. 2007, 72, 5342-5349 Simila, S. T. M.; Reichelt, A.; Martin, S. F. Tetrahedron Lett. 2006, 47, 2933-2936. Brimble, M. A.; Trzoss, M. Tetrahedron 2004, 60, 5613-5622. Pansare, S. V.; Adsool, V. A. Org. Lett. 2006, 8, 2035-2037, Thornqvist, V.; Manner, S.; Wendt, O. F.; Frejd, T. Tetrahedron 2006, 62, 1179311800. Singh, B.; Sahu, P. K.; Sahu, B. C ; Mobin, S. M. J. Org. Chem. 2009, 74, 60926104. Hanessian, S.; Margarita, R.; Hall, A.; Johnstone, S.; Termblya, M.; Parlanti, L. J. Am. Chem. Soc. 2002, 124, 13342-13343. Robichaud, J.; Tremblay, F. Org. Lett. 2006, 8, 597-600. Enev, V. S.; Drescher, M.; Mulzer, J. Org. Lett. 2008,10, 413—416. Dudley, G. B.; Engel, D. A.; Ghiviriga, I.; Lam, H.; Poon, K. W. C ; Singletary, J. A. Org. Lett. 2007, 9, 2839-2842. Jones, S. B.; He, L.; Castle, S. L. Org. Lett. 2006, 8, 3757-3760. Wakefield, B.; Halter, R. J.; Wipf, P. Org. Lett. 2007, 9, 3121-3124. Jiao, L.; Hao, E.; Fronczek, F. R.; Graca, M.; Cicente, H.; Smith, K, M. Chem. Commun. 2006, 3900-3902. Paley, R. S.; Estroff, L. A.; Gauget, J-M.; Hunt, D. K.; Newlin, R. C. Org. Lett. 2000, 2, 365-368. Greshock, T. J.; Funk, R. L. Tetrahedron Lett. 2006, 47, 5437-5439. Chippindale, A. M.; Davies, S. G.; Iwamoto, K.; Parkin, R. M.; Smethurst, C. A. P.; Smith, A. D.; Rodriquez-Solla, H. Tetrahedron 2003, 59, 3253-3265. Liu, Y.; Han, T.-X.; Yang, Z.-J.; Zhang, L.-R.; Zhang, L.-H. Tetrahedron Asymm. 2007,75,2326-2331. Hanna, I.; Ricard, L. Org. Lett. 2000, 2, 2651-2654. Boyer, F.-D.; Hanna, I. Tetrahedron Lett. 2001, 42, 1275-1277. Skaanderup, P. R.; Madsen. R. Chem. Comm. 2001,1106-1107. Marco-Contelles, J.; de Opazo, E. J. Org. Chem. 2002, 67, 3705-3717. Czuk, R.; Prell, E.; Reissmann, S. Tetrahedron 2008, 64, 9417-9422.

Chapter 5 Large-Ring Carbocycles 126. 127. 128. 129. 130. 131. 132. 133. 134. 135. 136. 137. 138. 139. 140. 141. 142. 143. 144. 145. 146. 147. 148. 149. 150. 151. 152. 153. 154. 155. 156. 157. 158.

575

Yokoe, H.; Sasaki, H.; Yoshimura, T.; Shindo, M.; Yoshida, M.; Shishido, K. Org. Lett. 2007, 9,969-971. Nosse, B.; Schall, A.; Jeong, W. B.; Resiser, O. Adv. Synth. Catal. 2005, 347, 1869-1874. Oliver, S. F.; Hogenauer, K.; Simic, O.; Antonello, A.; Smith, M. D.; Ley. S. B. Angew. Chem., Int. Ed. 2003, 42, 5996-6000. Krafft, M. E.; Cheung, Y. Y.; Kerrigan, S. A.; Abboud, K. A. Tetrahedron Lett. 2003, 44, 839-843. Mehta, G.; Lakshminath, S. Tetrahedron Lett. 2006, 47, 327-330. Srikrishna, A.; Dethe, D. H. Org. Lett. 2004, 6, 165-168. Nakashima, K.; Inoue, K.; Sono, M.; Tori, M. J. Org. Chem. 2002, 67, 6034-6040. Michalak, K.; Michalak, M.; Wicha, J. Tetrahedron Lett. 2005, 46, 1149-1153. Mehta, G.; Likhite, N. S. Tetrahedron Lett. 2008, 49, 7113-7116. Llyod-Jones, G. C; Murray, M.; Stentiford, R. A.; Worthington, P. A. Eur. J. Org. Chem. 2000, 975-985. Lysenko, I. L.; Lee, H. G.; Cha, J. K. Org. Lett. 2006, 8, 2671-2673. Zhao, L.; Burnell, D. J. Org. Lett. 2006, 8,155-157 Paquette, L. A.; Sauer, D. R.; Cleary, D. G.; Kinsella, M. A.; Blackwell, C. M.; Anderson, L. G. J. Am. Chem. Soc. 1992,114, 7375-7387. Singh, B.; Sahu, P. K.; Sahu, B. C; Mobin, S. M. J. Org. Chem. 2009, 74, 60926104. Bennasar, M.-L.; Zulaica, E.; Tummers, S. Tetrahedron Lett. 2004, 45, 6283-6285. Chattopadhyay, S. K. Ghosh, D.; Neogi, K. Synth. Comm. 2007, 37, 1535-1543. Miller, S, J.; Kim, S.-H.; Chen, Z.-R.; Grubbs, R. H. J. Am. Chem. Soc. 1995, 117, 2108-2109. Kariuki, B. M.; Owton, W. M; Percy, J. M.; Pinant, S.; Smith, C. A.; Spencer, N.; Thomas, A. C; Watson, M. Chem. Comm. 2002, 228-229. Ashworth, I. W.; Miles, J. A. L.; Nelson, D. J.; Percy, J. M. Singh, K. Tetrahedron 2009, 65, 9637-9646. Comer, E.; Rohan, E.; Deng, L.; Porco, J. A. Org. Lett. 2007, 9, 2123-2126. Boyer, F.-D.; Hanna, I.; Nolan, S. P. J. Org. Chem. 2001, 66, 4094-^1096. Gravier-Pelletier, C; Andriuzzi, O.; Le Merrer, Y. Tetrahedron Lett. 2002, 43, 245-248. Michalak, K.; Michalak, M.; Wicha, J. Tetrahedron Lett. 2005, 46, 1149-1153. Paquette, L. A.; Tae, J.; Arlington, M. P.; Sadoun, A. H. J. Am. Chem. Soc. 2000, 122, 2742-2748. Krafft, M. E.; Cheung, Y. Y.; Abboud, K. A. J. Org. Chem. 2001, 66, 7443-7448. Takao, K.; Watanabe, G.; Yasui, H.; Tadano, K. Org. Lett. 2002, 4, 2941-2943. Rodriguez, J. R.; Castedo, L.; Mascarenas, J. L. Chem. Eur. J. 2002, 8,2923-2930. Michaut, A.; Miranda-Garcia, S.; Menendez, J. C; Rodriguez, J. Org. Lett. 2004, 6, 3075-3078. Singh, V.; Pal, S.; Tosh, D. K.; Mobin, S. M. Tetrahedron 2007, 63,2446-2454. Paquette, L. A.; Efremov, I. J. Am. Chem. Soc. 2001,123,4492^501. Bourgeois, D.; Pancrazi, A.; Ricard, JL.; Prunet, J. Angew. Chem., Int. Ed. Engl. 2000, 39, 725-728. (b) Bourgeois, D.; Mahuteau, J.; Pancrazi, A.; Nolan, S. P.; Prunet, J. Synthesis 2000, 869-882. Schütz, S.; Ma, C; Ricard, L.; Prunet, J. J. Organomet. Chem. 2006, 691, 54385443. Codesido, E. M.; Rodnquez, J. R.; Castedo, L.; Granja, J. R. Org. Lett. 2002, 4, 1651-1654.

576

159. 160. 161. 162. 163. 164. 165. 166. 167. 168. 169.

170. 171. 172. 173. 174. 175. 176. 177. 178. 179. 180. 181. 182. 183. 184. 185. 186. 187. 188. 189. 190.

Name Reactions for Carbocyclic Ring Formations

Garcia-Fandino, R.; Aldegunde, M. J.; Codesido, E. M.; Castedo, L.; Granja, J. R. J. Org. Chem. 2005, 70, 8281-8290. Singh, B.; Sahu, P. K.; Sahu, B. C ; Mobin, S. M. J. Org. Chem. 2009, 74, 60926104. Bennasar, M.-L.; Zulaica, E.; Tummers, S. Tetrahedron Lett. 2004, 45, 6283-6285. Clark, J. S.; Marlin, F.; Nay, B.; Wilson, C. Org. Lett. 2003, 5, 89-92. Rodriquez, J. R.; Costedo, L.; Mascarenas, J. L. Org. Lett. 2000,2, 3209-3212. Clark, J. S.; Northall, J. M.; Marlin, F.; Nay, B.; Wilson, C ; Blake, A. J.; Waring, M. J. Org. Biomol. Chem. 2008, 6, 4012^025. Tang, H.; Yusuff, N.; Wood, J. L. Org. Lett. 2001, 3, 1563-1566. Winkler, J. D.; Rouse, M. B.; Greany, M. F.; Harrison, S. J.; Jeon, Y. T. J. Am. Chem. Soc. 2002,124, 9726-9728. Hayakawa, I.; Asuma, Y.; Ohyoshi, T.; Aoki, K.; Kigoshi, H. Tetrahedron Lett. 2007, 4S, 6221-6224. Larrosa, I.; Da Silva, M. I.; Gomez, P. M.; Hannen, P.; Ko, E.; Lenger, S. R.; Linke, S. R.; White, A, J. P.; Wilton, D.; Barrett, A. G. M. J. Am. Chem. Soc. 2006, 128, 14042-14043. (a) Caggiano, L.; Castoldi, D.; Beumer, R.; Bayon, P.; Tesler, J.; Gennari, C. Tetrahedron Lett. 2003, 44, 7913-7919. (b) Castoldi, D.; Caggiano, L.; Bayon, P.; Costa, A. M.; Capella, P.; Sharon, O.; Gennari, C. Tetrahedron 2005, 61, 21232139. Nakamura, T.; Oshida, M.; Nomura, T.; Nakazaki, A.; Kobayashi, S. Org. Lett. 2007, 9, 5533-5536. Nicolaou, K. C ; Harrison, S. T. J. Am. Chem. Soc. 2007,129,429-440. Brown, M. K.; Hoyveda, A. H. J. Am. Chem. Soc. 2008,130, 12904-12906. Renxulli, M. L.; Rocheblave, L.; Avramova, S. I.; Galletti, E.; Castagnolo, D.; Tafi, A.; Corelli, F.; Botta, M. Tetrahedron 2007, 63, 497-509. Galletti, E.; Avramova, S. I. Renzulli, M. L.; Corelli, F.; Botta, M. Tetrahedron Lett. 2007, 45,751-754. Wenz, M.; Grossbach, D.; Beitzel, M.; Blechert, S. Synthesis 1999, 607-614. Caussanel, F.; Wang, K.; Ramachandran, S. A.; Deslongchamps, P. J. Org. Chem. 2006,71,7370-7377. Kim, S. H.; Figueroa, L; Fuchs, P. L. Tetrahedron Lett. 2004, 38, 2601-2604. Furstner, A.; Gastner, T.; Weintritt, H. J. Org. Chem. 1999, 64, 2361-2366. Bamford, S. J.; Lucker, T.; Speckamp, W. N.; Hiemstra, H. Org. Lett. 2000, 2, 1157-1160. Boger, D. L.; Hong, J. J. Am. Chem. Soc. 2001,123, 8515v8519. Harrington, P.S.; Tius, M. A. Org. Lett. 1999,1, 649-651. Smith, A. B.; Basu, K.; Bosanac, T. J. Am. Chem. Soc. 2007,129, 14872-14874. Smith, A. B.; Bosanac, T.; Basu, K. J. Am. Chem. Soc. 2009,131, 2348-2358. Ichige, T.; Okano, Y.; Kanoh, N.; Nakata, M. J. Org. Chem. 2009, 74, 230-243. Furstner, A.; Langemann, J. Synthesis 1997, 792-798. Kamat, V. P.; Hagiwara, H.; Katsumi, T.; Suzuki, T.; Ando, M. J. Chem. Soc, Perkin Tranas. 1, 1998, 2253-2254. Kamat, V. P.; Hagiwara, H.; Katsumi, T.; Hoshi, T.; Suzuki, T.; Ando, M. Tetrahedron 2000, 56, 4397^1403. Trost, B. M.; Dong, G.; Vance, J. A. J. Am. Chem. Soc. 2007, 129,450-4541. El-Azizi, Y.; Schmitzer, A.; Collins, S. K. Angew. Chem., Int. Ed. 2006, 45, 968973. Zakarian, J. E.; El-Azizi, Y.; Collins, S. K. Org. Lett. 2008,10, 2927-2930.

Chapter 5 Large-Ring Carbocycles 191. 192. 193. 194.

577

Smith, A. B.; Adams, C. M.; Kozmin, S. A.; Paone, D. B. J. Am. Chem. Soc. 2001, 123, 5925-5937. Kotha, S.; Mandai, K. Eur. J. Org. Chem. 2006, 5387-5393. Mori, K.; Ohmori, k.; Suzuki, K. Angw. Chem., Int. Ed. 2009, 48, 5658-5641. Smith, A. B.; Mesaros, E. F.; Meyer, E. A. J. Am. Chem. Soc. 2006, 128, 52925299

578

5.4

Name Reactions for Carbocyclic Ring Formations

Thorpe-Ziegler Cyclization

Richard J. Mullins and Michael W. Danneman 5.4.1 Description The Thorpe-Ziegler cyclization is the intramolecular condensation of dinitriles to yield imines which ultimately tautomerize to the corresponding enamine.1 The enamine can be hydrolyzed to yield the ß-ketonitrile; under more harsh conditions, hydrolysis of the nitrile results in decarboxylation to yield the ketone.

NaOEt, EtOH

c&»»> CN

5.4.2 Historical Perspective In 1904, Jocelyn Field Thorpe and co-workers conducted the first studies of the intermolecular dimerization of nitriles.2 A short time later, the first example of a dinitrile cyclization was described by Moore and Thorpe.3 Initially, all products of dinitrile cyclization reactions were characterized as imines. However, in 1955, it was determined that the product of the cyclization of adiponitrile was in actuality an enamine. The enamine structure for the product of dinitrile cyclizations has since been confirmed through numerous other studies, and makes sense chemically. The conjugated enamine would be expected to be more stable than the corresponding nonconjugated ß-iminonitrile. In 1933, Ziegler and co-workers demonstrated that Thorpe's reaction could be applied toward the synthesis of cyclic ketones ranging from seven to 33 carbons in size.5'6 In a series of studies, it was demonstrated that these cyclic ketones were optimally produced by conducting the reaction under highly diluted conditions to avoid bimolecular reactions. Diethyl ether was found to be the ideal solvent, and soluble amide bases were found to give the most efficient cyclization.6-1 l The contributions made by Ziegler toward the development and generalization of this reaction have resulted in its being known as the Thorpe-Ziegler cyclization. For a more thorough discussion of the history of the Thorpe-Ziegler cyclization, the reader is directed here.12

Chapter 5 Large-Ring Carbocycles

5.4.3

579

Mechanism

The Thorpe-Ziegler cyclization is characterized by a relatively straightforward mechanism. As demonstrated below, deprotonation of dinitrile 1 results in the formation of the anionic species 2. Intramolecular cyclization in a manner similar to the well-known Dieckmann condensation yields 3. Workup under aqueous conditions then produces imine 4, which immediately tautomerizes to the conjugated enamine 5. CN CN

NaOEt

CN

CN CN CN

CN NH

^>—NH·,

5.6.4. Variations and Improvements Although the Thorpe-Ziegler name is typically limited to the selfcondensation of nitriles, many other intramolecular condensation reactions are often referred to in the same manner when a nitrile is the electrophile.13 While this review focuses specifically on the dinitrile variant of the reaction, the reader's attention is directed to a wealth of literature on these related reactions, commonly used in heterocycle synthesis. 14-26 A few examples of these reactions are shown below, as used for the preparation of 6,27 -7,15 and 8.28

NaOMe EtO

MeOH

N-S^N

Name Reactions for Carbocyclic Ring Formations

580

À" N H

NaOEt C02Et

EtOH, reflux, 1h

N H

80%

C02Et

HSCH2C02Me

»_ NaOMe, MeOH 94%

5.4.5

8

H2N

cOOMe

Synthetic Utility

The Thorpe-Ziegler cyclization has found substantial utility in synthetic endeavors. Specifically, it has found broad scope for a variety of heterocyclic compounds. As demonstrated in the work of Salaheldin and coworkers, a one-pot alkylation/Thorpe-Ziegler sequence resulted in the synthesis of 3-aminopyrroles.29 Treatment of β,β-enaminonitrile 9 with chloroacetonitrile under basic conditions results in alkylation to produce intermediate 10, which undergoes a spontaneous Thorpe-Ziegler cyclization to create the 3-aminopyrrole 11. Notably, the use of Et3N as base resulted in a substantial improvment compared to the use of K2CO3 in DMF.

CU

,CN

Et3N reflux 91%

A similar procedure, demonstrated by Tsolomitis and co-workers, has found utility in the synthesis of pentasubstituted pyrroles.30 Treatment of amide 12 with POCI3 results in intermediate 13, which, upon reaction with malononitrile is presumed to yield intermediate 14. Before isolation of 14, the Thorpe-Ziegler cyclization occurs to give pyrrole 15.

581

Chapter 5 Large-Ring Carbocycles

r

,Ph

Ph POCI3

H3C^ ^Nk ^.CN

Ύ o

HaC^N^^CN

CH2(CN)2

OPOCI2

12

Et3N

13

I

r

Ph

H3C./N. NC

H

.CN 58%

r-Ph

C

3 \^-N

N C \

CN

NH2

15

14

The Thorpe-Ziegler reaction has also been used for the preparation of functionalized thienopyridines. Alkylation of 16 by chloroacetonitrile first results in the formation of 17. Treatment of 17 with sodium ethoxide results in a Thorpe-Ziegler reaction to produce 18 in excellent yield. Thienopyridine 18 can also be secured directly by treatment of 16 with chloroacetonitrile in the presence of ethoxide.20

S

CN

NaOEt EtOH 90%

NaOEt, EtOH

An interesting rearrangement was observed in the Thorpe-Ziegler reaction of 19.31 Aimed at the synthesis of a benzothiazepine, treatment of 19 with sodium hydride resulted in the formation of intermediate 20. While protonation of 20 would have provided the desired benzothiazepine, instead, intramolecular attack by the enolate resulted in the formation of 21. Subsequent expulsion of sulfur and aromatization provided the 2morpholinoquinoline 22 in good yield.

Name Reactions for Carbocyclic Ring Formations

582

ΟΞΝ

,J

CN NaH DMSO 62%

19

20

The Thorpe-Ziegler reaction has been commonly used for the synthesis of spirocyclic ketones.32 An example of this comes from the work of Chande and coworkers in their efforts toward the synthesis of novel thiobarbituric acid derivatives.33 In this synthesis, 1,3-ditolylthiobarbituric acid 23 is reacted with acrylonitrile in the presence of sodamide in DMF at ambient temperature. Following successive Michael additions to produce 24, a spontaneous Thorpe-Ziegler cyclization occurs to provide enamine 25. Exhaustive hydrolysis and subsequent decarboxylation of 25 result in the desired spirocyclohexanone derivative 26.

mc ^

S

J - ^ N ^ ^

25

NH2

.CH,

r^y

NaNH2, DMF

HaC

CH, ^ ^ N ^ N

Chapter 5 Large-Ring Carbocycles

583

The Chande group has similarly used the Thorpe-Ziegler annulation for synthesis of spiroketones containing antibacterial, antitubercular and anticancer properties.34 For example, the Michael addition of 27 with acrylonitrile in the presence of sodamide yields 28. When diadduct 28 is exposed to base, the Thorpe-Ziegler intramolecular ring closure occurs to yield the desired derivative 29. Hydrolysis and decarboxylation then occurs to give compound 30, possessing antitubercular activity. Ketone 31, which possesses anticancer and antibacterial activity, has been produced in a similar manner.

NaNH2, acrylonitrile N^O CH3 27

DMF, 15°C,2h 92%

ri^^i

S-/~~~CN

^ ^ ^ N ^ O CH3

NaOEt BOH, reflux, 4 h 75%

31 The Thorpe-Ziegler reaction is well-known for its ability to construct medium sized rings and large macrocycles.12'35^0 Studies done by Anderson and Breazeale focused on the formation of a 1,3-bridged azulene structure utilizing an intramolecular ring closure via a Thorpe-Ziegler reaction.41 Exposure of dinitrile 32 to base under high-dilution conditions results in 33 upon hydrolysis. Although the yield was modest, these efforts resulted in the first synthesis of a 1,3-bridged azulene.

584

Name Reactions for Carbocyclic Ring Formations

(CH2)5CN

32

(CH2)5CN

PhLi A/-methylaniline Et 2 0, 0 °C 33

The Thorpe-Ziegler reaction has been widely utilized in the synthesis of natural products.42^18 Deslongchamps and co-workers used the cyclization for construction of the D-ring of the stemodane skeleton in the natural product (+)-maritimol. (+)-Maritimol (36), isolated from Stemodia maritime^ was used as a Caribbean folk medicine for the treatment of venereal diseases. Cyclization of dinitrile 34 was followed by acidic hydrolysis to yield tetracycle 35. The synthesis of 35 represented a formal synthesis of the natural product, as this intermediate could be elaborated to 36 using conditions developed by Piers and co-workers.47 CNCN KOf-Bu, f-BuOH, 85 °C

^. then H3PO4, AcOH, 115 °C 68%

°

"•OH

Malassene and co-workers recently examined the application of the Thorpe-Ziegler cyclization for synthesis of perhydrohistrionicotoxin, a skin extract of the Colombian poison arrow frog, Dendrobates histrionicus.42'49 Under standard conditions, dinitrile 37 was directly converted into spiropiperidine 38 through the Thorpe-Ziegler cyclization, completing construction of the carbon framework of perhydrohistrionicotoxin.

Chapter 5 Large-Ring Carbocycles

585

LDA THF, -80 °C to rt

CN

70%

Satoh and Wakasugi have developed a creative method for the synthesis of cyclopentenones involving a Thorpe-Ziegler cyclization.5 ' Beginning with a-chlorovinylsulfoxide 39, conjugate addition of cyanomethyllithium results in the preparation of 40. Notably, this reaction, which results in a quaternary center, proceeds in very high yield for a variety of vinylsulfoxide substrates. Treatment of 40 with LDA results in the formation of an a-sulfinyl carbenoid which is trapped by 2lithiopropionitrile. Subsequent Thorpe-Ziegler cyclization and elimination of the toluenesulfenyl anion then occurs to produce enaminonitrile 41. Hydrolysis and decarboxylation finally results in the isolation of cyclopentenone 42. Of note, this reaction has proven general for a large number of substrates. Several different vinylsulfoxides and 2-lithionitriles have been utilized to expand the scope of this reaction. As demonstrated in the preparation of 43, when a chiral sulfoxide is utilized, the reaction proceeds with a high degree of enantioselectivity for formation of the quaternary chiral center at C-4 of the cyclopentenone.550

d

QOi ,0

+

\j _to| C|

r°\^\J^+<°

LiCH2CN THF, -78 °C

39

2. CH3CH(Li)CN, THF 76% H3PO4, AcOH

°

99%

1. LDA, THF,-78 °C

H 2 0, reflux 87%

ci

X

—' 40

I NC

NC ^-0 / — \ ) s ^ N H 2

QO<X O

x

—' ^ - ^ C H 3 41

c;Kja, 0

r-Ή /

O \ /^-^

w

42

CH3

to1

Name Reactions for Carbocyclic Ring Formations

586

H3C

Sv"tol

LiCH2CN

H,C-

HX-

THF, -78 °C 97%, 99% de 1.LDA, THF, -78 °C 2. CH 3 CH(Li)CN, THF

»

H3C

CHS(0)tol CI

H,C

79%, 99% ee

5.4.6

Experimental CNCN KOf-Bu, i-BuOH, 85 °C then H3PO4, AcOH, 115 °C 68%

». O

Enedione (35)43 Dinitrile 34 (85 mg, 274 μιηοΐ) in a deoxygenated tert-BuOK solution (2 mL, 1% in tert-BuOH) was heated in an oil bath for 2.5 h at 85 °C. Upon cooling, the mixture was diluted with CH2CI2 and hexane, acetic acid (10 μ ί ) was added and the mixture was evaporated several times from hexane. The residue was dissolved in CH2CI2, washed with water, dried over MgSC>4, filtered through a cm long silica pad, which was eluted with ether. Evaporation of the solvent afforded the enaminonitrile (85 mg, 100%) as an off-white solid. It was carried over to the hydrolysis step without delay. The enaminonitrile from the previous experiment was heated for 37 h in a deoxygenated acid mixture (2 mL, made by admixture of 4 mL 85% H3PO4, 10 mL AcOH and 1 mL H 2 0) in an oil bath at 110 °C. Upon cooling, the mixture was diluted with CH2CI2, washed with water, dried over MgS04 and evaporated. Flash chromatography (hexane/ether/CH2Cl2 3:3:1) of this crude material afforded enedione 35 (53 mg, 68%) as white plates.

Chapter 5 Large-Ring Carbocycles

587

Na, toluene reflux 74% 45

NH2

^CN

4'-Imino-10-oxospiro[anthracene-9,l'-cyclohexane]-3-carbonitrile (45).32 Compound 44 (1.5 g, 5 mmol) was dissolved in 25 ml of toluene. To this, pulverized sodium (0.12 g, 5 mmol) was then added. The reaction mixture was refluxed for 8 h. To this reaction mixture, a little methanol was added to react with the unreacted sodium metal. From the reaction mixture, solvent was removed by vacuum distillation and the remaining solid contents were poured onto crushed ice and acidified using aqueous 2 N HC1 to pH 2-3. The dark colored solid obtained was then filtered, washed with water, vacuum dried, and recrystallized from benzene/pet ether to afford pure compound 45 (1.11 g, 74%). 5.4.7 References 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18. 19.

Li, J. J. Name Reactions: A Collection of Detailed Reaction Mechanisms, 3rd ed. SpringerBerlin-Heidelberg, 2006, pp. 592-593. Baron, H.; Remfry, F. G. P.; Thorpe, Y. F. J. Chem. Soc. 1904, 85, 1726-1761. Moore, C. W.; Thorpe, J. F. J. Chem. Soc. 1908, 93, 165-187. Hammer, C. F.; Hines, R. A. J. Am. Chem. Soc. 1955, 77, 3649-3650. [R] Taylor, E. C; McKillop, A. The Chemistry of Cyclic Enaminonitriles and o-Amino Nitriles, Interscience, New York, 1970; Ch. 1. Ziegler, K.; Eberle, H.; Ohlinger, H. Liebigs Ann. 1933, 504, 94-130. Ziegler, K.; Lüttringhaus, A. Liebigs Ann. 1934, 511, 1-12. Ziegler, K.; Weber, K. Liebigs Ann. 1934, 512, 164-171. Ziegler, K.; Aurnhammer, R. Liebigs Ann. 1934, 513,43-64. Ziegler, K.; Hechelhammer, W. Liebigs Ann. 1937, 528, 114-142. Ziegler, K.; Holl, H. Liebigs Ann. 1937, 528, 143-154. [R] Schaefer, J. P.; Bloomfield, J. J. Org React. 1967, 15, 1-44. [R] Granik, V. G.; Kadushkin, A. V. Adv. Heterocycl. Chem. 1998, 72, 79-125. Ivanov, A. S.; Tugusheva, N. Z.; Solov'eva, N. P.; Granik, V. G. Russ. Chem. Bull., Int. Ed. 2002,57,2121-2128. Ivanyuk, T. V.; Kadushkin, A. V.; Solov'eva, N. P.; Granik, V. V. Mendeleev Commun. 1993,4, 160-161. Fedorov, A. E.; Shestopalov, A. M.; Belyakov, P. A. Aim. Chem. Bull., Int. Ed. 2003, 52, 2063-2069. Dotsenko, V. V.; Krivokolysko, S. G.; Litvinov, B. P.; Chernega, A. N. Chem. Heterocycl. Compd. 2007, 43, 599-607. Koditz, J.; Rudorf, W. D.; Härtung, H.; Heinemann, F. Liebigs Ann. Chem. 1993, 1003-1007. Ryndina, S. A.; Kadushkin, A. V.; Solov'eva, N. P.; Granik, V. G. Russ. Chem. Bull, Int. Ed. 2002, 51, 854-859.

588 20. 21. 22. 23. 24. 25. 26. 27. 28. 29. 30. 31. 32. 33. 34. 35. 36. 37. 38. 39. 40. 41. 42. 43. 44. 45. 46. 47. 48. 49. 50. 51.

Name Reactions for Carbocyclic Ring Formations Abdel-Rahman, A. E.; Bakhite, E. A.; Moamed, O. S.; Thabet, E. A. Phosphorus, Sulfur, and Silicon 2003,178, 89-106. Abdel-Rahman, A. E.; Bakhite, E. A.; Al-Taifi, E. A. J. Chem. Res. 2005, 7,461-468. Kaigorodova, E. A.; Konyushkin, L. D.; Kambulov, Yu.; Krapivin, G. D. Chem. Heterocycl. Compd. 1997, 33, 752-753. Semioshkin, A. A.; Artemov, V. A.; Ivanov, V. L., Ptashits, G. M; Petrovskii, P. V.; Shestopalov, A. M; Bregadze, V. I.; Litvinov, V. P. Chem. Heterocycl. Compd. 1998, 34, 688-691. Wei, H.; Cai, J.; Sun, M.; Ji, M. Heteroat. Chem. 2007,18, 236-238. Yakovlev, M. Y.; Kadushkin, A. V.; Solov'eva, N. P.; Granik, V. G. Heterocycl. Commun. 1998, 4, 245-252. Botsi, S.; Tsolomiti, G.; Hamilakis, S.; Tsolomitis, A. Heterocycl. Commun. 2008, 14, 233-236. Mohamed, O. S.; Al-Taifi, E. A.; El-Emary, T. I.; Bakhite, E. A.-G. Phosphorus, Sulfur, and SiliconlOOT, 182, 1061-1082. Ivanov, A. S.; Tugusheva, N. Z.; Alekseeva, L. M.; Granik, V. G. Russ. Chem. Bull., Int. Ed. 2003,52, 1182-1189. Salaheldin, A. M.; Oliveira-Campos, A. M. F.; Rodrigues, L. M. ARKIVOC 2008, 14, 180-190. Tsolomiti, G.; Tsolomiti, K.; Tsolomitis, A. Heterocycl. Commun.2001,13, 235-238. Fathalla, W.; Marek, J.; Pazdera, P. Heterocycl. Commun. 2002, 8, 79-82. Chande, M. S.; Khanwelkar, R. R.; Barve, P. A. J. Chem. Res. 2007, 8, 468^171. Chande, M. S.; Suryanarayan, V. Heterocycl. Commun. 2006,12, 415-418. Chande, M. S.; Verma, R. S.; Barve, P. A.; Khanwelkar, R. R.; Vaidya, R.B., Ajaikumar, K. B. Eur. J. Med. Chem. 2005, 40, 1143-1148 Hurd, R. N.; Shah, D. H. J. Org. Chem. 1973, 38, 390-394. Fry, E. M.; Fieser, L. F. J. Amer. Chem. Soc. 1940, 62, 3489-3494. Allinger, N. L.; Nakazaki, M.; Zalkow, V. J. Am. Chem. Soc. 1959, 81,4074^1080. Allinger, N. L.; Greenberg, S. J. Amer. Chem. Soc. 1959, 81, 5733-5736. Allinger, N. L.; Greenberg, S. J. Am. Chem. Soc. 1962, 84, 2394-2402. Rodriguez-Hahn, L.; Parrà M., M.; Martinez, M. Synth. Commun. 1984,14, 967-972. Anderson, A. G.; Breazeale, R. D. J. Org. Chem. 1969, 34, 2375-2384. Malassene, R.; Vanquelef, E.; Toupet, L.; Hurvois, J.; Moinet, C. Org. Biomol. Chem. 2003, 7,547-551. Toro, A.; Nowak, P.; Deslongchamps, P. J. Am. Chem. Soc. 2000,122, 4526-4527. Dansou, B.; Pichon, C; Dhal, R.; Brown, E.; Mille, S. Eur. J. Org. Chem. 2000, 8, 1527-1533. Linders, J. T. M.; Flippen-Anderson, J. L.; George, C. F.; Rice, K. C. Tetrahedron Lett. 1999, 40, 3905-3908. Luyten, M.; Keese, R. Tetrahedron 1986, 42, 1687-1691. Piers, E.; Abeysekara, B. F.; Herbert, D. J.; Suckling, I. D. J. Chem. Soc, Chem. Commun. 1982, 7, 404-406. [R] Fleming, F. F.; Shook, B. C. Tetrahedron 2002, 55, 1-23. Malassene, R.; Toupet, L.; Hurvois, J.-P.; Moinet, C. Synlett 2002, 6, 895-898. Satoh, T.; Wakasugi, D. Tetrahedron Lett. 2003, 44, 7517-7520. Wakasugi, D.; Satoh, T. Tetrahedron 2005, 61, 1245-1256.

Name Reactions for CarbocycUc Ring Formations Edited by Jie Jack Li Copynght © 2010 John Wiley & Sons, Inc.

Chapter 6 Transformation of Carbocycles

589

6.1 6.2 6.3 6.4 6.5 6.6

590 600 675 688 698 710

Blanc Chloromethylation Reaction Asymmetric Friedel-Crafts Reactions: Past to Present Houben-Hoesch Reaction Kolbe-Schmitt Reaction Vilsmeier-Haack Reaction von Richter Reaction

590

6.1

Name Reactions for Carbocyclic Ring Formations

Blanc Chloromethylation

Richard J. Mullins and Reid M. Faylor 6.1.1

Description

The Blanc reaction is the Lewis acid-promoted installation of a chloromethyl group onto an aromatic or heteroaromatic ring, using formaldehyde, or a synthetic equivalent, in combination with hydrochloric acid.1

o 6.1.2

H2CO ZnCI2, HCI

f^j

Cl

\ ^

Historical Perspective

Discovered in 1877, the Friedel-Crafts reaction is one of the more important and useful organic transformations. This class of reactions is generally considered to include all Lewis acid-promoted electrophilic alkylations and acylations of aromatic rings. Due to their synthetic utility, Friedel-Crafts reactions have been extensively studied and used across a broad and diverse area of chemical research. In 1898, the first chloromethylation of benzene was performed by Grassi and Maselli. Twenty-five years later, the reaction was extensively redeveloped by Gustave Louis Blanc3 while he was director at the Intendance militaire aux Invalides.1 Although his reaction conditions do not differ from the original conditions of Grassi and Maselli, his efforts earned him the honor of having the reaction bear his name. That the reaction seems closely related to the Friedel-Crafts reaction should not be surprising, as Blanc studied under Charles Friedel in Paris. In 1932, Quelet4 used the Blanc procedure, replacing formaldehyde with aliphatic aldehydes in the reaction with phenolic ethers. The resulting reaction mixtures were found to contain α-chloroalkyl derivatives. Although the conditions are virtually identical and the reaction proceeds via the same basic mechanism, the Blanc chloromethylation is often referred to as the Quelet reaction. Over time, the reaction has become a rather important synthetic method in organic chemistry, as the chloromethyl group can be easily converted into a variety of functional groups. A number of different procedures have been used to effect this transformation. In addition to formaldehyde, several formaldehyde equivalents have been used, including

Chapter 6 Transformations of Carbocycles

591

paraformaldehyde, a-trioxymethylene, and diethyl- or dimethyl-formal, among others.5 Several different catalysts have also been employed, with zinc chloride, sulfuric acid, and acetic acid being especially useful among these.5 While the reaction was first applied to aromatic hydrocarbons, a variety of aromatic rings containing activating and deactivating substituents have been employed with considerable success. For a more thorough discussion of the history of the Blanc chloromethylation, its scope and limitations as well as its use in synthesis prior to 1963, the reader is directed to excellent reviews by Fuson and McKeever5 and Olah and Tolgyesi. 6.1.3

Mechanism

There are two basic mechanistic pathways, which have been proposed for the Blanc reaction. Both involve electrophilic aromatic substitution, but differ with regards to the identity of the electrophilic species and the point at which the halogenation occurs. The subtle differences between the two mechanisms may depend on the conditions involved. Studies by Olah and Yu7 have suggested the following mechanism is operable when a Lewis acid such as ZnCh is employed. Following protonation of formaldehyde and addition of chloride ion, a second protonation occurs giving rise to complex 1, which acts as the electrophile in the reaction with benzene (2). Attack of 1 by benzene results in the formation of the resonance-stabilized cation 3, with displacement of a water molecule. Finally, removal of a proton from 3 results in rearomatization of the benzene ring to provide 4.

H

O X

H

+ 2HCI

ZnCI2 ■

Q P C I ♦ H20

+ CI^OH2ZnCI3 +

Q P O ♦ H*

An alternate mechanism, suggested by Ogata and Okano, has precedence in the absence of a Lewis acid. Protonation of formaldehyde activates it for nucleophilic attack by formation of cation 5. Attack of 5 by benzene once more results in the formation of resonance stabilized cation 6. Loss of a proton regenerates the aromatic ring, forming benzyl alcohol (7),

592

Name Reactions for Carbocyclic Ring Formations

which then undergoes subsequent displacement by HC1 to produce benzyl chloride (4). O H

% H

H^H 5 OH

OH

^

HCI

2

^ V ^ O H

+ H+

CI

Although the mechanism above is considered generally correct, there have been multiple studies,7-12 which have attempted to delineate the more subtle aspects of the mechanism. For an extensive review on some of the earlier mechanistic studies, the reader is directed here.13 6.1.4

Variations and Improvements

In lieu of the catalysts ZnCU, SnCU and BF3 traditionally employed in the Blanc chloromethylation reaction, Sugi and co-workers have pioneered the use of Group 3 and 4 metal inflates to effect the transformation.14 Three of these inflates, Sc(OTf)3, Yb(OTf)3 and Sm(OTf>3, were shown to provide yields similar to those obtained under standard conditions. It is important that these Lewis acids can be used catalytically with loadings as low as 10 mol %. In addition, recovery and reuse of the catalyst is possible, without significant loss in activity. This work is significant, in that it avoids several problems associated with the use of traditional Lewis acids in the Blanc reaction. Primarily, there must be a stoichiometric amount of catalyst in regard to the substrate, which makes work up procedures tedious. The high corrosivity, susceptibility to water and low recoverability can cause environmental problems.14 Furthermore, these catalysts can form carcinogenic chloromethylethers and promote chlorination of the aromatic ring.15

Chapter 6 Transformations of Carbocycles

593

One drawback of the above procedure is the expense of the inflates, making them unsuitable for industrial purposes. Thus the search for other environmentally conscious and effective Lewis acid catalysis systems has resulted in the use of ionic liquids. Desired for their low vapor pressure, stability in a wide temperature range, and recyclability, ionic liquids are popular green alternatives to traditional solvent systems. Wang and coworkers have used one such ionic liquid, l-ethyl-3-methylimidazolium tetrafluorborate ([emim]BF4) as a promoter for the chloromethylation of a number of aromatic hydrocarbons.16 In the absence of [emim]BF4, the chloromethylation of m-xylene (8) underwent slow conversion, requiring 48 h to achieve 63% conversion. In contrast, the use of 0.3 equiv [emim]BF4 resulted in 92% conversion in just 7 h. Similar improvements including shorter reaction times, higher conversion, milder conditions and easy recycling were realized using the ionic liquid [Ci2mim]Br as promoter.17 i, "

Λ ^

+HCI + (CH 2 0) n

[emim]BF4

Issues of regioselectivity in the Blanc chloromethylation and related Friedel-Crafts reactions have been studied extensively. As is common with a majority of electrophilic aromatic substitution reactions, substitution typically occurs ortho or para to electron-donating substituents, with issues of steric strain playing a role in the relative ratio of ortho and para products. The Blanc reaction is typically somewhat regioselective, favoring the paraisomer but accompanied by lesser amounts of the ortho product.5 An additional difficulty in the Blanc reaction is the tendency for activated aromatic rings to undergo polychloromethylation under the typically harsh reaction conditions. For example, in the chloromethylation of benzene, the product benzylchloride (4) is often accompanied by small amounts of /»-xylylene dichloride 10, as well as a small amount of diphenylmethane, the product resulting from Friedel-Crafts alkylation of benzene with benzylchloride (4).3'5 With more activated ring systems, such as phenols, the reaction is increasingly difficult to control, resulting often in the formation of polymeric materials 5

ZnCI 2 , HCI 60 °C

594

Name Reactions for Carbocyclic Ring Formations

One solution to the aforementioned problem, realized by Tundo and co-workers, involved the addition of quaternary ammonium salts to the typical Blanc reaction mixture.18 For example, addition of hexadecyltrimethylammonium bromide to normal Blanc reaction conditions with eumene results in a two-phase system, where the reaction proceeds with high conversion (~ 89%) and high selectivity for formation of the monochloromethyl derivative (99%). Under these conditions, virtually none of the diphenylmethane product is observed. 6.1.5 Synthetic Utility The Blanc chloromethylation has found use across a wide spectrum of aromatic and heteroaromatic compounds. For a more thorough discussion of the use of the Blanc chloromethylation in synthesis before 1963, especially involving aromatic hydrocarbons, the reader is directed to excellent reviews by Fuson and McKeever and Olah and Tolgyesi.6 To ensure that this review has relatively broad scope, a few examples from these reviews are highlighted below. The use of methylchloromethyl ether in conjunction with SnCU, as an alternate procedure for chloromethylation, is demonstrated in the reaction of 1,3,5-trisopropylbenzene (12), yielding benzyl chloride 13.5 CICH2OCH3 SnCI4, CS2 0°C, 2 h 81%

13

While acetophenones are typically resistant to chloromethylation due to the electron-withdrawing ability of the carbonyl, some highly substituted acetophenones have been known to undergo this reaction. In the case of 14, treatment with HC1 and paraformaldehyde results in the production of 15 in high yield.19 H2CO HCI rt, 16 h 77%

Chapter 6 Transformations of Carbocycles

595

Although phenols are known to react very rapidly under Blanc conditions and often result in polymeric materials, when substituted with an electron-withdrawing substituent they become suitable substrates for this reaction. As shown below, /7-nitrophenol (16) is chloromethylated using the dimethylacetal of formaldehyde giving 17 in relatively high yield.20 CH2(OCH3)2 HCI, H2S04 70°C, 5 h 69%

In a similar manner, work done by Quelet also focused on the chloromethylation reaction of substituted aromatic rings such as pmethylanisole.4 Mallory and co-workers used this reaction as a key step in their synthesis of 2-methylphenanthrene (21).21 In the initial stages of synthesis, /»-methylanisole (18) was converted to 2-(chloromethyl)-4methylanisole (19). Subsequent ylide formation and Wittig reaction with benzaldehyde to give 20 was followed by a photocyclization to produce 21. A similar chloromethylation reaction has been used in efforts toward the synthesis of macrocyclic ligands.22 OCH

OCH·, CH2CI

1 PPh3

xy|ene

2. PhCHO 38%

Owing to their high electron density, furans have been especially useful in the Blanc chloromethylation.23"25 In particular, Pevzner and coworkers have recently published numerous papers using this combination of reactants.26~30 Directed toward the synthesis of dialkoxyphosphorylmethyl derivatives of furans, introduction of a chloromethyl side chain was envisioned to proceed through the Blanc reaction. Thus treatment of 22

Name Reactions for Carbocyclic Ring Formations

596

under standard conditions resulted in the formation of 23 in high yield.31 Notably, in spite of the steric hindrance imposed by the /-butyl group at C-5 of the furan ring, substitution occurs exclusively at C-4. This regioselectivity is likely a result of the electron-withdrawing ester at C-2, which prevents substitution at C-3.

(H3C)3C

^ο^

α

CH2O

π-τ

Jl \

C02CH3

22

ZnCI2, HCI CCI44, 55 °C

Λ

JT\

(HaCkC^V,

co

2CH 3

23

76%Ό

Alternatively, the direct chloromethylation of diethoxyphosphinoylmethyl compounds 24 and 26 was carried out to give 25 and 27, respectively, both of which were obtained in high yield.32 The fact that these reactions proceed at low temperatures demonstrates the high reactivity of furans when not substituted with an electron-withdrawing group, as in 22 above. ?

f\ O 24

H3

°

O

26

i,r ^ = - "v^M?

P-OEt OEt

CH

2°

9

n-t

ZnCI2, HCI CHCI3, 0 °C 91%

25

?i „ .

CH.O CH 20

C|

OEt

ZnCI2,HCI CHCI3,0 °C 89%

H

3

\ C ^

O 0

> ^

^

27

Hara and co-workers used the Blanc reaction for the synthesis of a key intermediate toward a series of benzodiazepines. Since their goal was ultimately the installation of an ethyl substituent at C-4, in lieu of a formaldehyde precursor like trioxane or paraformaldehyde, acetaldehyde was used, in a manner similar to the Quelet reaction. As commonly observed under these conditions, alkene 30 was isolated along with product 29. Given that the alkene 30 was also a desired product, the reaction mixture was simply heated with pyridine, resulting in complete conversion to 30. To complete the installation of the ethyl substituent, the alkene of 30 was subsequently reduced.

Chapter 6 Transformations of Carbocycles

Jl \\ H3C^O C02C2H5 28

CH3CHO

597

:~Xxr

-

HCI, ZnCI2 H3C" x O / ^C0 2 C 2 H5

CH2CI2, 0 °C

^C^O'^CO^Hs 30

pyridine reflux, 3 h, 28%

Thiophene, another π-excessive heterocycle, was originally used in the Blanc reaction in 1942 by Blicke and Burckhalter.34 Following their procedure, a large scale synthesis of 32 has been developed. Notably, in reaction with un-substituted thiophene (31), the chloromethyl group is selectively installed at the 2-position.35 This particular chloromethylation has been frequently used as a method for incorporation of the thiophene core into other molecules.36'37 H2CO, HCI »

31

o°c

//

41%

\N

CI

32

Benzothiophenes have also found utility in the Blanc chloromethylation, especially in the area of medicinal chemistry. As demonstrated by Cross and co-workers during their efforts toward the synthesis of selective thromboxane synthetase inhibitors, treatment of 33 under the standard conditions resulted in 34.41 While benzothiophene typically substitute preferentially at C-3, in this case the methyl at C-3 forces substitution to occur at C-2. ,CH,

EtOoC

.CH3

Et0 2 C

H2CO, HCI

CI

ZnCI 2 , CHCI3, 18 h 33

45%

34

6.1.6 Experimental

II % 35

CH 2 0 C02CH3

ZnC|2

HC|

CH 2 CI 2 , 30 °C 32%

CI

11

k

0^C02CH3

36

598

Name Reactions for Carbocyclic Ring Formations

Methyl 5-(chloromethyl)furan-2-carboxylate (36) Dry HC1 gas was introduced into the stirred mixture of methyl furan-2carboxylate (35, 25.2 g, 0.2 mol), paraformaldehyde (6.0 g, 0.2 mol), and ZnCl2 (30.0 g, 0.22 mol) in CH2C12 (100 mL) for 3 h at 30-35 °C. The reaction mixture was poured into 80 mL water. The mixture was extracted with CH2CI2 (3 x 30 mL). The organic phase was combined and dried with anhydrous Na2SC>4. The solution was evaporated to dryness. The remaining residue was distilled and the distillate collected as a colorless oil in 32.3% yield (11.3 g).

37

—η

H2CO, HCI

S

H20, 1.5 h 45%

CcT 38

3-(Chloromethyl)benzo [b] thiophene (3 8) HCl(g) was bubbled vigorously through a mixture of thianaphthene (37, 17.0 g, 126.68 mmol), 37% aqueous formaldehyde (15 mL), and concentrated HCI (15 mL) until the reaction temperature rose to 65 °C. At this time, the flow of HCI gas was reduced to a slow stream which was maintained for 1.5 h. The reaction mixture was diluted with Η 2 0 (50 mL) and subsequently extracted with ether (2 χ 50 mL). The combined ethereal extracts were dried over Na2SÜ4 and concentrated under reduced pressure to yield a straw-colored liquid: 21.0 g (90.7%). 6.1.7

References

1.

[R] Li, J. J. Name Reactions: A Collection of Detailed Reaction Mechanisms, 3rd ed. Springer, New York, 2006, p. 61. Grassi, G.; Maselli, C. Gazz. Chim. Ital. 1898, 28, 477. Blanc, G. L. Bull. Soc. Chim. Fr. 1923, 33, 313. Quelet, R. Compt. Rend. 1932, 195, 155. [R] Fuson, R. C; McKeever, C. H. Org. React. 1942, /, 63-90. [R] Olah, G.; Tolgyesi, W. S. In Friedel-Crafts and Related Reactions, vol. II, part 2, Olah G., ed. Interscience, New York, 1963, pp. 659-784. Olah, G. A.; Yu, S. H. J. Am. Chem. Soc. 1975, 97, 2293-2295. Ogata, Y.; Okano, M. J. Am. Chem. Soc. 1956, 78, 5423-5425. Szmant, H. H.; Dudek, J. J. Am. Chem. Soc. 1949, 71, 3763-3765. Brown, H. C; Nelson, K. L. J. Am. Chem. Soc. 1953, 75, 6292-6299. Tyrlik, S. K.; Radziwonka, Z.; Piasecka-Maciejewska, K. Bull. Pol. Acad. Sci., Chem. 1986, 34,351-358. Uribe, M. I. O.; Salvador, A. R.; Gulias, A. I. Ind. Eng. Chem. Res. 1987, 26, 1725-1735. [R] Belen'kii, L. I.; Vol'kenshtein, Yu. B.; Karmanova, I. B. Russ. Chem. Rev. 1977, 46, 891-903. Kishida, T.; Yamauchi, T.; Kubota, Y.; Sugi, Y. Green Chem. 2004, 6, 57-62. Kishida, T.; Yamauchi, T.; Komura, K.; Kubota, Y.; Sugi, Y. J. Mol. Catal. A: Chem. 2006, 246,268-275.

2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15.

Chapter 6 Transformations of Carbocycles

16. 17. 18. 19. 20. 21. 22. 23. 24. 25. 26. 27. 28. 29. 30. 31. 32. 33. 34. 35. 36. 37. 38. 39. 40. 41.

599

Wang, Y.; Shang, Z.-C; Wu, T.-X. Synth. Commun. 2006, 36, 3053-3059. Fang, Y.; Deng, Y.; Qinggang, R.; Huang, J.; Zhang, S.; Huang, B.; Zhang, K. Chin. J. Chem. Eng. 2008,16, 357-360. Selva, M.; Trotta, F.; Tundo, P. Synthesis 1991, //, 1003-1004. Fuson, R. C; McKeever, C. H. J. Am. Chem. Soc. 1940, 62, 784-785. Buehler, C. A.; Kirchner, F. K.; Diebel, G. F. Org. Synth. 1940, 20, 59. Mallory, F. B.; Rudolph, M. J.; Oh, S. M. J. Org. Chem. 1989, 54,4619-4626. Dijkstra, P. J.; Skowronska-Ptasinska, M.; Reinhoudt, D. N.; den Hertog, H. J.; van Eerden, J.; Harkema, S.; de Zeeuw, D. J. Org. Chem. 1987, 52,4913-4921. Schmuck, C; Machon, U. Eur. J. Org. Chem. 2006,4385^1392. Elliott, M.; Janes, N. F.; Pearson, B. C. J. Chem. Soc. (C) 1971, 17, 2551-2554. Su, H.; Nebbioso, A.; Carafa, V.; Chen, Y.; Yang, B.; Altucci, L.; You, Q. Bioorg. Med. Chem. 2008, 16, 7992-8002. Pevzner, L. M. Russ. J. Gen. Chem. 2005, 75, 774-781. Pevzner, L. M. Russ. J. Gen. Chem. 2003, 73, 1877-1880. Pevzner, L. M. Russ. J. Gen. Chem. 2002, 72, 1085-1089. Pevzner, L. M. Russ. J. Gen. Chem. 2003, 73,260-266. Pevzner, L. M. Russ. J. Gen. Chem. 2004, 74, 1182-1184. Pevzner, L. M. Russ. J. Gen. Chem. 2003, 73, 1715-1724. Pevzner, L. M. Russ. J. Gen. Chem. 2008, 78, 206-209. Hara, T.; Kayama, Y.; Mori, T.; Itoh, K.; Fujimori, H.; Sunami, T.; Hashimoto, Y.; Ishimoto, S. J. Med. Chem. 1978, 21, 263-268. Blicke, F. F.; Burckhalter, J. H. J. Am. Chem. Soc. 1942, 64, 477-480. Wiberg, K. B.; McShane, H. F. Org. Synth. 1949, 31-33. Lee, W.-H.; Kong, H.; Oh, S.-Y.; Shim, H.-K.; Kang, I.-N. J. Polym. Sei., Part A: Polym. Chem. 2009, 47, 111-120. Hou, J.; Tan, Z. A.; Yan, Y.; He, Y.; Yang, C; Li, Y. J. Am. Chem. Soc. 2006, 128, 4911^1916. Efange, S. M. N.; Mash, D. C; Khare, A. B.; Ouyang, Q. J. Med. Chem. 1998, 41, 44864491. Abadi, A. H. Arch. Pharm. Med. Chem. 2004, 337, 383-390. Podea, P. V.; Irimie, F. D.; Tosa, M. I.; Paizs, C; Irimie, F. D. Tetrahedron: Asymmetry 2008,79,500-511. Cross, P. E.; Dickinson, R. P.; Parry, M. J.; Randall M. J. J. Med. Chem. 1986, 29, 1643-1650.

600

6.2

Name Reactions for Carbocyclic Ring Formations

Asymmetric Friedel-Crafts Reactions: Past to Present

Jeffrey A. Campbell 6.2.1

Description

This chapter will review basic concepts of Friedel-Crafts (F-C) reactions and then will present a chronological breakdown of key highlights of F-C asymmetric bond homologation methodology applied to aromatic ring systems developed over the years. The F-C reaction is of broad scope and for the purpose of this chapter will be limited to two categories, the alkylation or acylation reactions of aromatic or heteroaromatic compounds to afford the corresponding alkyl and acyl arenes, respectively. Both F-C alkylation and acylation reactions involve replacement of a hydrogen atom of an aryl moiety swith an alkyl or acyl group by the reaction of an alkylating or acylating agent in the presence of a catalyst (Lewis acid with and without a cocatalyst, Bronsted acid, etc.). Generalized Friedel-Crafts Intermolecular Alkylatiori Reaction

o

RiXor R,H LA and/or H +

R

R

R-iOH or |

1

j R , and/or [j

>

(Ri' = rearranged R-i)

Generalized Friedel-Crafts Intermolecular Acylatiori Reaction

o

0

RAY

^LA and/or H +

ck

In the F-C alkylation reaction, carbocation intermediates, generated from the reaction of a wide variety of catalysts with alkyl halides, alkenes, and alcohols, are used to alkylate an aromatic ring. Other alkylating agents that can be used include alkynes, esters, aldehydes, ketones, amines (via diazotization), epoxides, thiols, thiocyanates, ethers, sulfides, sulfates, nitro groups and acyclic/cyclic alkanes. Depending on substrate and reaction conditions, skeletal rearrangements, elimination, polyalkylation, isomerization, cracking and polymerization reactions also fall within the

Chapter 6 Transformations of Carbocycles

601

scope of this reversible reaction. Monoalkylation of the arene moiety without skeletal rearrangement (Ri to Ri') of the electrophile or the pendant alkyl side chain of the alkylated arene product, polyalkylation, and complexation of the Lewis Acid with the reagents/product(s), are the greatest synthetic limitations of this reaction. In addition, incorporation of substituents onto a monoalkyl arene scaffold under kinetic versus thermodynamic control, can result in different dialkylarene product orientations (ortholpara versus meta dialkyl substitution, respectively). The F-C acylation reaction, industrially useful for the production of aromatic ketone and aldehydes, involves generation of an acylium containing electrophile which is used to acylate an arene moiety. It is generated from the reaction of Lewis acids with carboxylic acids, carboxylic acid halides or carboxylic active esters. In addition, ketenes and nitriles may be used as the source of the electrophile. Overall this reaction is generally not reversible and skeleletal rearrangements of the reagent or products seldom occur. Polyacylation does not usually occur primarily for two reasons: (1) the acylium ion is more stable than the corresponding carbocation so the Ri group cannot easily rearrange, and (2) the acyl moiety of the product of this reaction is usually complexed more strongly with the Lewis acid than the starting arene which deactivates the ring toward further acylation. The inherent limitation of F-C alkylation reaction in preparation of primary alkyl arenes due to skeletal rearrangement can be overcome using a two-step sequence involving F-C arene acylation followed by reduction of the resulting ketone to a methylene moiety.1-5 6.2.2

Historical Perspective

The Friedel-Crafts (F-C) reaction was discovered at the Sorbonne (Paris, France) in 1877 by Charles Friedel (1832-1899) and James Mason Crafts (1839-1917) who met while studying under C. A. Wurtz in 1861. Due to common research interests involving organosilicon compounds, they began a collaboration during the period of 1863-1865. This partnership continued for 17 years, involved many areas of chemistry, including the F-C reaction, and resulted in close to 100 publications.3'5'6 Their first paper describing a general method for the synthesis of aromatic hydrocarbons and ketones, such as amylbenzene and benzophenone, proved revolutionary and is now referred to as F-C alkylation and acylation reactions, respectively.7 Over the course of their collaboration they extended the scope of the use of catalytic aluminium chloride to a wide variety of organic reactions: (1) reaction of alkyl, acyl chloride, and unsaturated compounds with aliphatic and aromatic hydrocarbons; (2) reactions of acid anhydrides, oxygen, sulfur, sulfur dioxide, carbon dioxide, and phosgene with aromatic hydrocarbons; (3) cracking of aliphatic and aromatic hydrocarbons, and (4) polymerization

602

Name Reactions for Carbocyclic Ring Formations

of unsaturated hydrocarbons. The breadth and chemical diversity introduced by these chemical pioneers was brilliant.8 6.2.3

General Friedel-Crafts Alkylation Mechanism

The traditional Friedel-Crafts alkylation reaction involves the reaction of an aromatic substrate with alkyl halide catalyzed by a Lewis acid to form an alkylated arene moiety. Alternative reactants other than alkyl halides, such as alcohol, alkenes and cyclic/acyclic alkanes, can be also be used in reaction with the aromatic substrate. The mechanism of other alkylating agents that provide sources of carbocations such as alkynes, esters, aldehydes, ketones, amines (via diazotization), epoxides, thiols, thiocyanates, ethers, sulfides, nitro groups, and sulfates will be inferred from the general mechanism and not discussed in detail.1-5'8 Many comprehensive F-C alkyl halide alkylation reviews, including books on this subject, have been reported by Price (1946)9, Olah (1964, 1973),3'5 Roberts and Khalaf (1984),4 and Olah (1991 and 2005).'' 8 In all cases, a carbocation intermediate is generated which is capable of reacting as the electrophile in a reversible electrophilic aromatic substitution (EAS) reaction. Mechanism of Alkyl Halides and Alcohols as Alkylating Agents Alkyl halides and alcohols can coordinate with typical Lewis Acids (LA) such as AICI3, TiCU, SbFs, BF3, ZnC^ or FeC^, to form LA complex-I, which can act as the electrophile. It should be noted that alcohols may be activated also by the use of Bronsted acids to form similar complexes forming water as a byproduct. Alternatively, tight ion pair complex-I where the Ri moiety can form a stable carbocation-II, can serve as the initial electrophile or rearrange to complexes containing a carbocation of similar or greater stability (III, Ri' + ). It is likely that primary alkyl groups proceed through a tight ion pair I (polar donor-acceptor complex), rather than via a free carbocation intermediate (Π) which would be rapidly trapped by the arene moiety. The extent of polarization of the Ri-X/R)-OMX3/Ri-OH2 + bond resulting in the formation of I, II or III depends on the structure of Ri, the nature of the acid catalyst used, and the solvent of the reaction. In general, the order of reactivity of alkyl halides with Lewis acids is C-F > C Cl>C-Br>C-L 1 _ 5 ' 8 ' 1 0

Chapter 6 Transformations of Carbocycles

603

Generalized Friedel-Crafts Intermolecular RX/ROH Alkylation Mechanism R!-X

Rì-OH

R^OH

MX n «

δ+ δR-,--X--MX n

MX n

δ+ δRr-0--MXn

,

«

ί

I

H

+

«

β Θ R!+MXn+1

„

© e R.,+OMX n

«

«

© Ri + H 2 0

·«

il

il

δ+ δ

" Rr-OH2

I

li

(RR denotes rearrangement took place) RìOrRV,® ~MXn+1 or ΘΟΜΧη

R^rR/

?NL. U >®,

+ l/U/lil

(π-Complex)

H

(σ-Complex)

+MX n+1 °^* or H2O

RR

e e R·,' + MX n+1

RR

® θ R,' + OMX n

1U

U!

RR

© RV + H 2 0

iii

,^^RiorRi

θ

or

,

► | n

+MX n

IV

The arene moiety can form a rapid π-complex with the formed complex ion I/II/III which can rearrange slowly to a σ-complex, a cyclohexadienyl cation known as a Wheland intermediate. This step is usually the ratedetermining step (RDS) whose existence was first postulated by Brown in the very first kinetics study of this reaction.11 In further support of the mechanistic intermediate, the detection of several σ-complexes stable at low temperatures have been reported. ' The aromatic ring moiety is generally regenerated by fast base abstraction of a proton with regeneration of the Lewis acid and HX formed. The actual RDS and reversibility of the overall mechanism, however, depends on a complex interplay of substrate and reaction conditions. Some evidence that this reaction may not proceed completely through true carbocation intermediates such as tight-ion pairs complexes of I, is that alkylation of arenes in the presence of Lewis catalysts with optically active oxiranes can give up to 100% inversion (vide supra).14'15 The majority of cases, however, show partial or total racemization indicating the significant involvement of carbocation intermediates. More compelling evidence is that a competitive ethylation study of toluene using methyl bromide and methyl iodide, gave different ortho/para/meta ratios.14'16 A duality (carbocation versus tight-ion pair) of mechanism can exist of which the actual operating mechanism depends on many factors: (1) nucleophilicity of arene, (2) nature and reactivity of the alkylating agent, (3) solvent, (4) catalyst, and (5) reaction temperature.17 Olah and Olah reported a competitive alkylation mechanism study of naphthalene in 1976 and postulated that the positional and substrate selectivities of napthalene F-C alkylation shed insight on the kinetically

Name Reactions for Carbocyclic Ring Formations

604

versus thermodynamic controlled product composition of the reaction. It was suggested that a π-complex such as Ι/Π was involved when highly electrophilic/highly basic arene moieties, resulting in the formation of the kinetically controlled product (1-substituted naphthalene analogue). In contrast, when weakly electrophilic Lewis acids or less basic arenes were used, the thermodynamic alkylation product (2-substituted naphthalene analogue) was produced via the intermediacy of the σ-complex (Π, Wheland intermediate). These results were later supported by related observations of Nakane and co-workers in 1978.1'18'19 Mechanism ofAlkenes, Alkynes and Alkane as Alkylating Agents (n- and σdonors) Reaction of Alkenes proceed through a similar intermediate V: H

i-i

|!|

-H

H+or

HMX4or6

H

In R 2 -"é s - -HH ^ «vera/ V- Further RR Possible

(other R R

products)

Reaction of alkanes via proton abstraction produce carbocation VI: R3

R:

;

£±

HMX4 or 6

R3

Κ2Λ VI- Further RR Possible

^:

several steos

R3

pf-«, \

^

(otner R R

proc |ucts)

Both alkenes and alkynes (π-donars) react with Bronsted acids as well as conventional Lewis acids (MX3, MX5, etc.) in the presence of a proton source such as water or acids of the formula HMX4 or HMX6 give similar carbocation intermediates (V) following Markovnikov's rule and can be trapped by arenes via the same EAS mechanism.5'8 Neat Lewis acids or even super Lewis acids (stronger than AICI3) are unsuccessful in these reactions without the addition of a proton donor cocatalyst. The addition of the cocatalyst is essential in allowing formation of a strong conjugate acid or carbocation to be formed. Alkanes and cycloalkanes (σ-donors) can undergo hydride abstraction reactions to produce reactive carbocation intermediates of type VI which can be also captured by arenes in similar fashion.8 Usually, strong acid donors on the order of super acids (equal or stronger than sulfuric acid) are required to

Chapter 6 Transformations of Carbocycles

605

generate the carbocation intermediate provided the C-H bond being abstracted has an appropriately low enough bond dissociation energy. 6.2.4

Key Friedel-Crafts Alkylation Reaction Variables

Lewis acid Catalysts: Use and Limitations Many kinds of aprotic and protic acid catalysts used as single agents and in combination have been reported: (1) Lewis acids (metal halides, metal alkyl/alkoxides), (2) Acidic oxides-sulfides (acidic chalcogenides such as alumina, silica as single agent/combination, clays and zeolites), (3) acidiccation exchange resins (Dowex, Amberlite), (4) Bronsted acids (regular and super proton acids), (5) Bransted-Lewis superacid combination, (6) solid superacids that include acidic and shape selectivity (ZSM-zeolites), and (7) metathetic cation forming agents such as silver salts (noncatalytic/stoichiometric use).1 Some frequently used Lewis acids include A1X3, BeCL;, CdCb, ZnCb, BF3, BX3, FeX3, GaX3, T1X4, SnX4, and various antimony halides (where X = Br, Cl). Comparative studies ranking Lewis acid activities have been reported.8'20a Actual activity, however, depends heavily on reaction conditions (reagent substrates, solvent, and temperature).20 Since most Lewis acid catalysts are destroyed in the aqueous workup step, this serves as a limitation for the recycling of moisture sensitive catalysts. Special measures can be taken, depending on the nature of the catalyst and appropriate reaction workup conditions employed, to permit effective recycling. The catalyst BF3 can be recovered from reaction mixtures and reused as it is a low boiling gas (b.p. -101 °C). Fujiwara (1986) has shown the use of lanthanide trihalidebased Lewis acids to promote F-C alkylations with both recovery and reuse of the catalyst without loss of catalytic activity.1'8'21 Effect ofCocatalyst on F-C Alkylation Reaction It has been determined that impurities such as moisture can accelerate this reaction, as AlCl3-promoted reactions conducted under strictly anhydrous conditions can occur at a significantly lower rate of reaction. Due to this observation, it was subsequently discovered that the addition of cocatalysts can accelerate the rate of this reaction, such as oxygen, proton-releasing substances (ROH), Bronsted acids, and cation/carbocation producing substances. ' For example, the F-C alkylation of arenes with alkenes and alkynes promoted by AICI3 was found to be cocatalyzed by trace amounts of moisture effecting an increase in both the rate and yield of the reaction; whereas the opposite was observed with use of FeCb as the cocatalyst.1'8'22

606

Name Reactions for Carbocyclic Ring Formations

Reactivity and Orientation of Monosubstituted Arenes Monosubstituted arenes show good reactivity with moderately activated substituents such as alkyl but do not proceed under normal conditions in the presence of other strongly deactivating electron-withdrawing groups, such as carboxyl, nitro, and sulfonyl functional group containing moieties. The reactivity limit appears to be arenes with a moderately deactivating group such as halogen and trihalomethyl. Substrates with more electron-releasing functional groups that are basic or containing easy exchangeable protons such as amino and hydroxyl, lead to loss of catalytic activity. In these cases, the reaction may proceed if the Lewis acid is used in greater 1:1 stoichiometry. One exception due to lower overall basicity, is the preparation of alkylated arylamines from arylamines and alkenes using aluminium anilides as catalyst.17 The orientation of an incoming alkylating agent to a monoalkylated arene under conditions favoring kinetic control is ortho or para, with the latter usually predominating due to steric reasons. There are many experimental parameters favoring kinetic control of the reaction. They include use of a reactive electrophile in a preferential noncoordinating solvent with basic arene as nucleophiles, as well as use of low reaction temperature, short reaction times, and minimal amount of weaker Lewis acid catalysts. Under conditions favoring thermodynamic control (elevated temperature, long reactions times, large amount of catalyst, stronger Lewis acid, less reactive arenes, less reactive electrophiles and absence of solvent), meta substitution usually predominates.4'8 Allen and Yats (1961) concluded that analysis of various f-butylations of toluene produce either 7/93 or 67/33 meta:para-to\xiQnQ with no ortho isomer formed under conditions of kinetic and thermodynamic control, respectively. Other monosubstituted arene having highly active electron-releasing groups (OR, NRCOR, NR2) and moderately deactivating groups such as halo due to arene resonance contribution are usually ortholpara directing under either kinetic or thermodynamic conditions. Alkyl Group Rearrangements and Reactions Involving Dealkylation and/or Transalkylation (Disproportionation). Since the alkylation reaction is reversible, rearrangement of the alkylating agent,24 as well as rearrangement of the pendant alkyl moieties of the formed alkylarene III can occur. In addition, the gain and loss of alkyl moieties of the formed alkylarene can occur through dealkylation-transalkylation disproportionation reactions. These reactions have some limitations, but may also be utilized to synthetic advantage. The likelihood of rearrangement is related to the stability of the carbocation formed (benzyl, 3° > 2° > 1°);

Chapter 6 Transformations of Carbocycles

607

whereas, the tendency of disproportionation of the Ri moiety is observed in similar order: i-butyl > /-butyl > «-butyl > Et > Me.8'25 General Disproportionation Reaction Scheme:

2 II ~

„RiOrFV

R-i or R r

AICU ^

Ri or R r

The likelihood of rearrangement of the alkyl group is clearly affected by temperature. One example is the alkylation of neat benzene by Ipatieff (1940) with H-chloropropane in the presence of AICI3 catalyst, where a 1.5:1 selectivity is observed in favor of w-propyl (1) over /-propylbenzene (2) at - 6 °C; whereas, the reverse is true at 35 °C.26 Other variables such as nature of the alkylating moiety, choice of solvent, and catalyst are also important in determining product composition.4 AICU CI

1

Temp -6 °C

(60%)

Temp 35 °C

(40%)

Alkylation-Dealkylation Reactions Sequences. Blocking Groups (tert-Butyl Moiety) R

R

—- u H2SO4

rr-"Wr-

S

°3

H

-r

R

ΌΗ

AICI3 excess »80% 5b

6b

Introduction of Removable

608

Name Reactions for Carbocyclic Ring Formations

The reversibility of the reaction allows alkyl blocking groups such as the tertbutyl moiety to be incorporated early into a reaction sequence and later removed after suitable functional group manipulation.27'10 An interesting general example is the preparation of an ortho substituted alkyl phenol 6a by selective or/Ao-sulfation of a /?crra-alkyl substituted /eri-butylbenzene 3, saponification of the resulting sulfonic acid 4 and fért-butyl removal of the corresponding phenol 5a via a retro-F-C alkylation sequence (Lewis acid usually AICI3 and arene based feri-butyl scavenger). Recently, use of TFA/Na2S204 or excess Lewis acid such as AICI329 has shown to eliminate the need for arene based scavengers such as toluene, anisole or dimethylaniline in removal of the fér/-butyl moiety. For example, removal of as many as three tert-butyl moieties of 5b using excess AICI3 afforded 6b in 80% yield. In addition, selective removal of an ortho- versus parasubstituted tert-butyl moiety has also been shown to be possible.29 Polyalkylation, Cracking, Isomerization, and Polymerization Reactions. Polysubstitution can be an issue and is primarily due to preferentially partitioning of the alkylated product with the catalyst because of heterogeneity in the reaction mixture. Minimization of this side product may be accomplished using the arene as solvent and with high speed stirring. This may seem contrary to the popular notion that electron-releasing groups overactivate the ring to induce polyalkylation. Kinetic studies clearly show that electron-releasing alkyl groups show only a modest rate enhancement (only 1.5-3.Ox as fast as benzene) and do not fully account for polysubstitution. In the industrial preparation of ethylbenzene from ethylene and benzene in the presence of AICI3 and cocatalyst water, the polyethylbenzene side product can be effectively recycled back to ethylbenzene.8,17'303 The F-C alkylation reaction has played a vital role in the historical evolution of many core chemical industries, including the petroleum industry. In fact, AICI3 was the first catalyst to demonstrate catalytic cracking, the isomerization and conversion of larger hydrocarbon chain petroleum products to smaller more branched hydrocarbon products necessary to the production of high-performance (high-octane) gasoline. This process, mediated through formation of both radical and carbocationic intermediates, however, was limited industrially by excessive coke (nonvolatile carbon) and other polymeric by product formation. It was subsequently discovered (late 1920s) that the use of natural clays or zeolites, was far more effective promoting catalytic cracking over AICI3. This process was adopted widespread industrially and use of higher performance aviation fuel that resulted was believed to have been responsible for the air superiority of the allies over Germany during WWII.30b

Chapter 6 Transformations of Carbocycles

609

Zeolites are complex bridging tetrahedral arrangements of silicon and alumina, each having four oxygen atoms as ligands. The silicon atom is neutral, whereas each aluminium atom has a negative charge that has associated with it a cation (such as natural clays that contain a sodium ion, Na+1). These resulting networks create pores of regular dimensions (order of multiple À size) that can be used to trap small organic molecules or the sodium cation exchanged with other cations to modulate its use as a powerful Lewis acid or Bransted acid. For example, using a cation exchange process, the sodium may be exchanged for ammonia (NH4+) which can be heated with the extrusion of ammonia. The result is that the ammonium cation is replaced by a proton producing a powerful Bransted acid. Zeolites may be used or modified from natural sources or produced artificially to modulate shape and size selectivity of the channels as well as the polarity.30b'c Relative Reactivity of Dihaloalkanes Boron Halide Catalyzed Haloalkylation with fluorohaloalkanes:

o ^ (n=2, m=0, X=l,Br,CI) (n=3, m=1,X=Br,CI) (n=4, m=2, X=Br,CI)

x

χ

o ^ ♦ σ^ 7 (63%, 92%, 94%) (0%) (0%)

8 (N/A) (89,90%) (80,84%)

The reactivity order of fluorohaloalkanes carbon halogen bond (type Ri-X) with Lewis acid such as boron trihalides (BX3) was C-F > C-Cl > C-Br > C-I whereas the reactivity order of the boron trihalide catalyst in the same study was BI3 > BBr3 > BCI3 > BF 3 . Complete monohalide alkylation selectivity of various primary alkyl monofiuorohalides (n = 3,4) with regioselective displacement of the fluoro moiety in the presence of BF3 catalyst was achieved by Olah (1964), albeit with rearrangement of 7 to 8 via capture of the more stable carbocation that was formed.31 A similar trend has been observed with other more reactive Lewis acids, such as AICI3, though dialkylation in this case may be competitive.4 It should be noted that alkylation of dihaloalkanes containing the same halogen atom leads to either intramolecular or intermolecular dialkylation, depending on the size of the methylene linker between the halogens of the reacting electrophile, the catalyst, and choice of reaction solvent.4

Name Reactions for Carbocyclic Ring Formations

610

6.2.5

General Friedel-Crafts A cylation Mechanism

O

RA

X3M. MX3

s*

Ri

X

'

vn or

ICEO +

ΜΧ4 /A V

l|

Vili

©

(rare)

θ

Ri + MX4 1 or U (shown) I,

δ

δ + .ΜΧ 3 0'

RA VII

RR

-

A

Ri

θ

Vili

©

!iì Χ-,Μ.

MX,

n 'Ri

+ νιι/νιιι

(π-Complex)

(σ-Complex)

IX

+ HX

The F-C acylation is very similar to F-C alkylation and can also display a duality of mechanism proceeding through a tight ion and acylium π- and σcomplex (VII and VIII, respectively) of the arene moiety. The actual operating mechanism depends on a complex interplay of substrate and reaction conditions as previously discussed with the alkylation mechanism.17 Although the EAS mechanism is the same, there is a significantly important difference. The arene σ-complex is often the rate-determining step (RDS) of the reaction; however, the reaction is not generally reversible as the final acylarene product of the reaction forms a tight complex (IX) with the catalyst. The formation of this complex can, but not always, prevent effective recycling of the catalyst from the catalyst-acylated product complex via ineffective halogen exchange between the catalyst and acylating agent.8 The acylium ion is particularly stable and generally does not easily undergo rearrangement reactions unlike F-C alkylations. If the acylium ion VIII can produce an especially stable carbocation and reacted with an arene of modest reactivity, side products can form via a competing F-C alkylation pathway. An example of such is the competing F-C acylation-alkylation pathways in the attempted pivaloylation of neat benzene versus anisole. The reaction of benzene with pivaloyl chloride in the presence of AICI3 catalyst produces fór/-butylbenzene as the major product, whereas the reaction of

Chapter 6 Transformations of Carbocycles

611

anisole produces primarily p-methoxy pivaloylphenone. Choice of substrate and reaction conditions can be important criteria in which pathway predominates.8'17 6.2.6

Key Friedel-Crafts Acylation Reaction Variables

Acyl Halide Reactivity and Catalyst Selectivity The majority of the catalysts discussed in the F-C alkylation section (vide supra) can also be used for the acylation reaction. A few commonly used Lewis acids are AICI3, SbF5, and BF3, but Bronsted acids, in general, are not effective in catalyzing acylation reactions with acyl halides. Some common electrophiles include carboxylic acids, halides, anhydrides, mixed active esters, ketenes, O-activated amidates derived from amides, nitriles, and carbon monoxide. The order of reactivity of acyl halides is usually but not exclusively I > Br > Cl > F. Due to complexation of Lewis acid catalyst with the carbonyl moiety, at least one and two equivalents of catalyst are usually required with acid chlorides and anhydrides, respectively. Cases where the LA catalyst may be conducted with high turnover involve use of arene substrates of high nucleophilicity with catalysts of moderate coordinating activity (FeCb, I2, ZnCb, and Fe). In similar fashion, use of the catalyst may be eliminated all together when highly active acylating agents such as mixed carboxylic sulfonic anhydrides are combined with highly nucleophilic arene substrates.14 Synthetic Advantages of Friedel-Crafts Acylation Versus Alkylation. O

\ JJ

1 ^ ° ÌS pJ AICI°

3

9

1 11 i f T i

^f

I

H2/Pd

A:O2H

10

·

rT^T^^

M1

PPA

^C02H

11

I

'

f^5^

y \ 12

O

Commercially inexpensive acyl chlorides, anhydrides and nitriles are frequently used in industry as acylating agents; however, carboxylic acids using strong Brensted acids (H2SO4, H3PO4, PPA), can also be particularly effective in promoting intramolecular F-C acylation.14 A particularly powerful synthetic example involves a three-step Haworth-type reaction sequence for introducing a fused ring onto an arene scaffold involving initial

Name Reactions for Carbocyclic Ring Formations

612

intermolecular acylation of p-xylenes 9 with 2-methyl succinic anhydride at the less hindered carbonyl moiety, reduction on the intermediate arylketone 10 with H2/Pd, and intramolecular acylation of the terminal carboxylic acid of 11 with PPA (polyphosphoric acid) to afford 12. Note that the intermediate reduction step allows complete regioselective incorporation of a nonbranched methylene moiety next to the aryl ring, a limitation of the F-C alkylation reaction.32'33"' An interesting one-pot tandem Lewis Acid Friedel-Crafts intermolecular acylation method with concomittant in situ reduction of the aryl ketone product has been reported by Jaxa-Chamiec.33c Treatment of toluene (13) with 4-chlorobutanoyl chloride and AICI3 gave an intermediate ketone 15 which was reduced in situ by use of either of Et3SiH of PMSH (polymethylhydroxysilane) to afford 16 in an impressive 85% yield from 13.

CI

CI

11

13

14

AlCh Et3SiH or PMSH/DCM

( 85% >

15(X = 0)

16(X = H,H)

Substrate Selectivity-Orientation in Synthesis The F-C acylation reaction does not generally undergo polyacylation due to a deactivating complexation of the product with Lewis acid catalyst. For this reason, arenes containing w-directing deactivating electron-withdrawing groups (CX3, sulfonyl, nitro, and various carbonyl-containing functional groups) usually prove unreactive. Known or//zo//>ara-directing groups such as alkyl, halogens, alkoxy, acetamido moieties work well, but aromatic amines and phenols suffer from competing N- versus O-alkylation side reactions. Protection of amine and alcohol functional groups is often required to ensure selective acylation. Many other complex regiochemical issues can be encountered in the F-C acylations of electron-rich arenes or heterocyclic arenes such as a complex interplay of competing electronic and steric directional control elements, which can work in synergy or against one another. Thus careful control of .reaction conditions can be essential for success in these types of reactions.

Chapter 6 Transformations of Carbocycles

613

AICh

19 Fenbufen (80%) 1:2 melt NaAICU »~200 °C

O

NH2

O

OAc

22 (45%)

23

10mol% Catalyst »CH3N02 100 °C

1) AICI3, DCM » 2)AICI3, PhH

MeO MeO 24 (Catalyst. Yield) BF3.OEt2 90% Sc(OTf)3 85% TfOH 86%

O

C02Me

25FPL64176(60%)

Carboxylic anhydrides can react once or twice with arenes, depending on conditions. The regioselective monoacylation of biphenyl (17) with succinic anhydride (18) in the presence of AICI3 results in a 80% yield of fenbufen (19), a nonsteroidal antiinflammatory (NSAID) analgesic drug.33d Triacetyl protected aminophenol 20, however, can be bisacylated under harsher conditions by reacting pthalic anhydride 21 in the melt with NaAICU at ~ 200 °C with concomitant cleavage of both the amino N-acyì protecting groups to afford 22 in 45% yield.336 Regioselective F-C acylations of carboxylic anhydrides can be accompanied by other Lewis acid mediated reactions in tandem. Recently, a general method for the Lewis acid mediated intramolecular cyclization of ßketo ester alkyl substituted arenes to functionalized 1 -indanones was reported by Fillion. Thus treatment of Meldrum's acid analogue 23 under a variety of

Name Reactions for Carbocyclic Ring Formations

614

Lewis acid conditions gave an intermediate F-C acylation adduci regioselectively which underwent decarboxylation at 100 °C to afford 1indanone 24 in 85-90% yield.33f~h An impressive example of reaction regioselectivity involving a tandem Friedel-Crafts acylation-alkylation sequence is the elegant synthesis of benzopyrrole calcium channel blocker 25 (FPL64716).3 ' Selective acylation of substituted pyrrole 26 with 2chloromethyl benzoyl chloride 27 using AICI3 in DCM, followed by phenyl alkylation of the intermediate benzylic chloride with benzene and AICI3 gave adduci 25 in an impressive 60% overall yield for the two-step sequence. Orientation of the incoming acyl group with an electron-releasing monosubstituted benzene, however, is predominantly para over ortho but selectivity can depend also on reaction conditions.14 For acylation or benzoylation of simple benzene monoalkylbenzene derivatives, the paraselectivity can approach 20:1 or greater.34 The reason for this was initially attributed to steric factors but a systematic analysis has shown that the relative reactivity of the electrophilic acylating agents can also affect the selectivity. For example, acylation of more reactive less stable acylium ion derivatives such as formyl and dinitrobenzoyl ion, the ortho:para selectivity can diminish greatly (~ l:l). 32 ' 35a Regioselectivity is also critical in the acylation of electron-rich heterocycles other than substituted benzenes. High regioselectivity (94:6 C-4 versus C-2 acylation) observed in the AICI3 promoted intramolecular acylation of 28 a 3-(indol-3-yl)propionyl chloride analogue, to adduci 29, a precursor in the synthesis of Uhle's ketone 30.35 A donor-acceptor complex between AICI3 and chloroacetyl chloride was proposed to drive the acylation reaction. A sodium methoxide mediated cleavage of the JV-BOC moiety of 29 completed the synthesis of 30 in 95% yield. H02C

1)SOCI2 2) CICH2COCI AICI3, DCE ^. 94 : 6 C-4 : C-2 Regioselectivity

NaOMe MeOH 29 (83%)

30 (95%)

Solvent Effects Highly coordinating solvents such as nitrobenzene, nitromethane, and carbon disulfide not only reduce the activity of the Lewis acid but also complex the acyl cation intermediate. This is also an issue with the use of more contemporary ionic liquids and supercritical CO2 as solvents used to . 35c potentiate chemical reactivity. c This complex modulates the overall

Chapter 6 Transformations of Carbocycles

615

reactivity of the electrophile with the resulting increase of steric bulk of this intermediate further increasing selectivity of the reaction with the arene moiety (increasing para- over ori/20-selectivity) for the less encumbered position. For example, acylation of chrysene and phenanthrene in nitrobenzene or carbon disulfide occurs at the sterically less encumbered outer ring; whereas, reaction with naphthalene under similar conditions leads to reaction primarily at the less sterically encumbered and less reactive 2position.8 Differences in the coordinating activity of these solvents can be exploited as well. For example, acetylation of naphthalene occurs primarily at the more reactive 1-position in carbon disulfide (kinetic control), but in nitrobenzene reaction occurs at the 2-position (thermodynamic control).17 6.2.7 Key Asymmetric Friedel-Crafts Developments, Improvements and Utility F-C Alkylation Reactions involving an Asymmetric Center F-C alkylations, involving manipulation or creation of an asymmetric center, require a delicate fine tuning of substrate and reaction conditions to achieve an adequate balance of yield (regioselectivity) and optical purity (enantioselectivity). Regioselectivity is complicated by selectivity of the electrophile (alkylating agent) with the nucleophile (arene component) and the coupling selectivity of the arene itself (i.e., or//zo/para-selectivity or positional selectivity of a heterocycle). For the enantioselective creation of a new asymmetric center using a prochiral electrophile as substrate, one can couple typically an electron-rich arene with a chiral Lewis acid catalyst or by performing a diastereoeselective alkylation reaction using a removable chiral auxiliary and catalyst. The chronological evolution of selected enantioselective F-C alkylations of arenes and related topics will be presented in the following sections: (1) Section A-chiral and achiral alkylating agents resulting in inversion or retention of configuration at the newly formed stereocenter, (2) Section B in 2 Parts-creation of new asymmetric centers by alkylation of carbonyl compounds (Section B, Part 1) and imines (Section B, Part 2) through use of chiral ligands coordinated to Lewis acids or use of chiral Bronsted acid catalysts, (3) Section C-indole polyalkylation issues related to Parts 1-2 of Section B, (4) Section D-asymmetric Pictet-Spengler reactions and related ./V-acyliminium cyclizations, and 5) Section E-asymmetric F-C Michael-type alkylations using chiral Lewis acids and chiral organocatalysts.

Name Reactions for Carbocyclic Ring Formations

616

A

Reaction with Chiral and Achiral A Ikylating Agents

Historically, the majority of cases involving F-C alkylation of an asymmetric center derived from an acyclic substrate, result in almost complete racemization. The alkylation of cyclic substrates, however, exhibited better level of stereocontrol, perhaps by the enforced proximity of the leaving group. The stereospecific F-C alkylation of (i?)-l,2-epoxypropane (1969) and (i?)-l,2-epoxybutane (1975) with benzene and CS2 in the presence of either AICI3 or SnCU, first reported by Nakajima and Suga, were landmark cases which shed some insight into the mechanistic complexicity of achieving both regio- and stereoselectivity in the reaction.15

/....
^O

PhH, AICI3(0.10eq.)

*~

^ V " ^9O H + 6%ee

CS 2 (1 eq.)

-10°C

31

iPV h

P hv< ^ ^ O H

-~1%ee

32

33

(40% 32:33, 51:49)

In the latter study, treatment of (./?)-1,2-epoxybutane (31) with 0.10 equiv of AICI3 and 1 equiv of CS2 at -10 °C gave 32 with almost complete inversion of configuration (96% ee), presumably via an intimate ion pair intermediate (vide supra). Poor regiochemical control was observed, however, due to competing chloride capture reactions (products not shown) and hydride transfer/phenyl capture isomerization reactions. Note that migration of the phenyl from the 2- to 3-position occurred in equal amount (51 : 49 of 32 and 33, respectively) in 40% yield from 31. With the weaker coordinating SnCU as catalyst at the same temperature (-10 °C), the ratio of 32:33 changed to 98:2; however, with a reduced 83% ee of the 2-phenyl alkylated product 32. PhH, AICI3

(1.2eq.l ~0 7 34 (Y=H,H) 35 (Y=0)

20-35 °C >50%

I

",. ^(CH 2 ) 2 COH Γ-35-40% ee(R) I 36 (Y=H,H) 37 (Y=0)

Some earlier studies by Brauman (1968-1969) in the alkylation of with benzene and AICI3 (> 1 equiv) with less reactive 2-methyl substituted cyclic ether36 and 4-methyl lactone37 substrates (34 and 35, respectively) at 20-35 °C gave much reduced stereochemical control (35:40%) ee, 36:37), with a

Chapter 6 Transformations of Carbocycles

617

reasonable yield (> 50%) of the phenyl alkylated products 36 and 37, respectively. Thus chiral 5-membered cyclic ether and lactones are less reactive electrophiles than oxiranes, requiring greater than stoichiometric amounts of AICI3 (1.25 equiv), possibly the cause of the higher level of racemization observed. Tuning of the substrate with the reaction conditions appears critical in maximizing the utility of this reaction.

PhH, AICI3

45-100% ee

-60%

A particularly interesting case, reported by Masuda in 1983, involved induction of asymmetry via a phenyl π-assisted cation nonsymmetrically bridged intermediate (38) with stereospecific cleavage of bond a over b. Thus reaction of either (-)-2-chloropropane (39) and (+)-l-chloro-2-phenylpropane (40) with benzene in the presence of AICI3 catalyst, gave the identical product, (-)-l,2-diphenylpropane (41), in yields as high as 60% and optical purities of 45-100% ee, depending on reaction conditions.38 The best results were obtained involved use of 0.1 equiv of AICI3 at 0 °C in benzene as solvent (30—40 equiv) to provide 41 in 100% optical purity from either 39 or 40 via a net retention and inversion of stereochemistry, respectively. C02Me

PhH AICI3 (-2.0 eq.) 50-80%

C02Me *~ >97% ee

42a (X=OS02CI ) 42b (X=OS02Me)

A landmark enantioselective F-C alkylation of benzene was reported by Piccolo in 1985 involving the use of acyclic substrates (sulfonates of alkyl lactates) with essentially complete transfer of chirality.15 Alkylation of benzene with either the (/?)- or (5)-enantiomer of chiral chlorosulfonates or mesylates (42a and 42b, respectively) derived from methyl lactate, in the presence of AICI3 as catalyst, affords 50-80%) yields of methyl-2phenylpropionate (43) with essentially complete inversion of configuration

Name Reactions for Carbocyclic Ring Formations

618

(> 97% ee). It is likely that use of a moderately nucleophilic arene neat as a low polarity solvent and coordination of the pendant amide and sulfonate leaving group to the Lewis acid contributed to the high degree of stereochemical control. Monosubstituted benzenes also appear to undergo alkylation with similar level of stereocontrol but suffered from very poor ortho:para-arene regioselectivity typical with most F-C alkylations. Kronenthal (1990) extended this reaction to cycloalkyl sulfates by demonstrating that the 4(R) and 4(S) diastereoisomers of jV-benzoyl-4mesyloxy-L-proline (44 and 45) also alkylate benzene with complete inversion of configuration to afford the corresponding trans- and cis-Aphenyl analogues 46 and 47 in 91% (75% isolated) and 76.3% yields, respectively. The isolation of optically pure 46 from 44 was reported to be accomplished on several hundred gram scale. A large excess (3.6 equiv) of AICI3 was required due to complexation with the carbonyl moieties. In either reaction, less than 0.2% of the other 4-phenyl epimer was detected. In addition, isolation of 8.5% and 14.5% of the corresponding 4-C1 epimer adducts (not shown) were isolated from 46 and 47, respectively. It was postulated that a Lewis acid complex with the benzoyl carbonyl moiety (electron-withdrawing group) inductively destabilizes formation of a carbocation intermediate, leading to the high inversion stereospecificity observed occurring through an exclusive SN2 pathway. Ph

PhH AICI3 (3.6 eq.) Bz 44:X=OMs, 48:X=F 49;X=CI

Temp 10 °C, Temp 25 °C, Temp 80 °C,

C02H 46 91% (75%) 70% 75%

30% 16.5%

Temp 10 °C,

0.2%

76.3%

OMs

Replacement of the 4(/?)-mesyloxy group (44) with fluoride (48) and chloride moieties (49), respectively, gave 70% and 75% of the inverted 4phenyl adduci (46). These reactions required progressively higher reaction temperatures, consistent with the reactivity order of halides with Lewis acids (vide supra). The lower reactivity of the 4(i?)-chloride (49) corresponded

Chapter 6 Transformations of Carbocycles

619

with isolation of 2% and 16.5% of the 4(i?)-chloro (not shown) and phenyl epimers (47), respectively. OEt

0.1NHCI -

50

OEt 52 (94% dr)

H2N OEt 53 (>94% ee)

The use of a chiral auxiliary directed F-C asymmetric alkylation was reported in 1987 by Schollkopf. Optically pure 2-arylglycine esters, important antibiotic pharmacophores, were prepared via halide inversion of diastereomerically pure alkyl chiral bislactim ester ethers. Treatment of 50, the chiral bislactim ester ether of cyclo-(L-Val-Gly), with an activated electron-rich arene such as 1,4-diethoxybenzene (51) and SnCU in DCM at 78 °C afforded predominantly bislactim adduci 52 (94% dr) in 65% yield. A hydrolysis operation then provided the 2-arylglycine ester 53 in > 94% ee. Treatment of 50 under analogous conditions using 1-methoxynapthalene as the arene coupling partner (not shown in scheme) gave the 4-napthalene bislactim alkylated product in similar yield (71%) and dr (95%), respectively. Reaction of 50 with anisole (also not shown in scheme) did not produce a regiochemically pure product, providing a 1:1 mixture of ortho/para-cowpled isomers. Arenes lacking electron-rich methoxy substituents were also not successful coupling partners in this reaction.40

Name Reactions for Carbocyclic Ring Formations

620

I BnO BnO BnO

OBn 54

Cp2ZrCI2-AgCI04 5 equiv. *25 °C, DCM

BnO^-°v J^J 57 (80% from 55)

58 (96% from 56)

A particularly interesting example of regio- and stereoselective of Carylglycosides, important biologically as antitumor agents, was reported by Matsumoto and co-workers in 1988. Treatment of glycosyl fluoride 54 with Lewis acid Cp2ZrCl2-AgC104 complex with either arene 55 or 56, provided the equatorial (ß-anomer) of C-aryl glycoside 57 and 58 in 80% and 96% yields, respectively. The formation of the ß-anomer presumably resulted from capture of the oxonium intermediate under conditions of thermodynamic control (5 equiv catalyst). Use of smaller amounts of catalyst (0.2-0.5 equiv) in the majority of cases resulted also in formation of the aanomer (kinetic product) in addition to the ß-anomer. All of the arenes reported contained at least one methoxy substituent.41

Chapter 6 Transformations of Carbocycles 61a(X,Y=H,H) 61d (X,Y=Br,H) 61 b (X,Y=H,Me) 61e (X,Y=CN,H) 61c (X,Y=MeO,H) 61f (X,Y=N02,H)

59, 60 (W=H, CI) Product

62 62* 63 64 65 66 67 68 69

W H H H CI CI H H H H

41-82% (*10 mol% of lnBr3 used) X H H H H H OMe Br CN N02

Y H H Me H Me H H H H

621

W

H 62-69 z H H H H H H H H H

% Yield (ee)

70 60 79 65 82 54 54 41 24

(99) (75) (99) (99) (99) (99) (99) (71) (ND)

Kotsuki in 1996 reported mild conditions for the regioselective and stereoselective F-C alkylation of indoles with chiral arene oxides. Treatment of (Ä)-styrene oxide 59 with indole (61a) gave the corresponding chiral ß-3indolyl alcohol 62 with inversion of configuration (88-92% ee, results not shown in scheme) using high pressure (10 kbar) or silica gel as the catalyst (7 days).42 Umani-Ronchi et al. (2002) have reported impressive results in the alkylation of arene oxides (59/60) with indoles of type 61 using catalytic InBr3 (1 mol %) in DCM to afford the corresponding alkylated products (6269) with essentially complete regiocontrol and stereocontrol (41-82% yield, > 99% ee). It is interesting that the use of greater than 5-10 mol % of InBr3 catalyst led to a considerably lower level of stereocontrol (75% ee vs. 99% ee, respectively) than 1 mol % in the coupling of 59 with 61a.43 Incorporation of a chloro moiety at the 3-position of the styrene oxide (60, W = Cl) or a methyl moiety at the 2-position of the indole (61b, Y = Me) had no effect on yield or stereocontrol (compare 62-65). Use of either electronically neutral, electron-donating or moderately electron-withdrawing groups at the 5-position of the indole (compare 61a,c,d respectively where X= H, OMe, Br) gave good yields and stereospecificity of 62, 66 and 67 (99% ee, 54-82% yield). Use of a strongly electron-withdrawing groups at the 5-position (68-9; X = CN, NO2), however, had a deleterious effect on both yield (41% and 24%, respectively) and reaction stereocontrol with each

Name Reactions for Carbocyclic Ring Formations

622

< 70% ee. Substitution of styrene oxide with propylene oxide, an aliphatic oxirane, under these reaction conditions led to complete nonregioselective opening of the aliphatic epoxide (~ 1:1 mixture not shown). Thus the combination of the coupling of arene oxide with a suitably electron-rich arenes is a critical factor in the success of this reaction to achieve a balance of both regiocontrol and stereocontrol.43

^ Ä ^ l (R)

3 equiv. racemate (S,S-isomer doesn't react)

(+/-)-72a(R1=CH2OTBS) (+/-)-72b (R^Ph) (+/-)-72c (R^Me) (+/-)-72d (R^COzMe) \

^ 74

3.5 mol% catalyst (R,R)-[CrSalen]SbF6 iBuOH.TBME, 4Ä MS, 0 °C

ASXR)

H

K" V Ì / \°" „ H D Ph ·)—

^.

Q

Compound % Yield (% ee) 73a (R^CHzOTBS) 96 (91 ) 73b (Ri=Ph) 82 (86) 73c(R 1 =Me) 99(72) 73d (R^COzMe) 85(80)

'Bu 'Bu 70 Y=CI, (R,R)-[CrSalen]CI 71 Y=SbF6, (R,R)-[CrSalen]SbF6

In 2004, Umani-Ronchi et al.44 discovered that chiral (R,R)[Cr(salen)]Y complexes (Jacobsen catalysts 70/71) could effectively undergo asymmetric F-C alkylation via kinetic resolution of racemic disubstituted epoxides. Treatment of 2-methylindole 74 with 3 equiv trans-1,2disubstituted epoxides (72a-d) and 3.5 mol % of (/?,#)-[Cr(salen)]SbF6 catalyst (71) provided excellent yields (82-99%) of the corresponding chiral ß-indolyl alcohols (73a-d) with good optical purity (72-91% ee). With this catalyst, only the (5,5)-isomer of 72a-d reacts to form the (i?,5)-isomer of 73a-d, respectively. As expected, the analogous enantiomerically pure cis-epoxide isomer of 72c, provides a diastereomer of 73c that has the oposite stereochemistry at the benzylic stereocenter (R instead of S, not shown). During the course of the resolution, the unreacted (7?r/?)-enantiomers of epoxides 73a-d are enantioenriched and can be isolated in excellent optical purity (91-99% ee) using only a slight modification of the reaction conditions (data not provided). Thus the F-C alkylation reaction can also be used to effect the

Chapter 6 Transformations of Carbocycles

623

kinetic resolution of racemic epoxides. The detailed mechanism and stereochemical model of these reactions was not discussed.44 (SIS)

Ph I JOH

v

"X»

H 75a-c (1.5 eq)

'Ph Ph ftfeso-76 (1 eq.) 5 mol% (R,R;-[CrSalen]CI TBME, 25 °C

1v

H ,,,>—^,„ R T^V^4 Ph

H Compound % Yield (% ee) (V-)-77a(R.,,R2=l-l) 98(93) (V-)-77b (R,=OMe, R2=H) 95 (90) 98 (98) (+/-)-77c (R^H, R,=Me)

The (i?,Z?)-[Cr(salen)]X catalyzed addition of indoles of type 75 was also applied by Umani-Ronchi (2004)44 to the asymmetric ring opening of meso-stilbene oxide (76). Treatment of indoles 75a-c (1.5 equiv) and mesostilbene oxide (1.0 equiv 76) in TBME with 5 mol% of (/?,#)-[Cr(salen)]Cl afforded the corresponding chiral (5',i?)-ß-indolyl alcohols (77a-c) in superb yield (95-98%) and enantiomeric purity (90-98% ee). Incorporation of a 2Me moiety or a 5-MeO moiety into the framework of the indole nucleus in place of H improves or reduces the optical purity of the alkylated product [compare 77c (98% ee) and 77b (90% ee) versus 77a (93% ee), respectively]. B Part 1. Chiral Lewis Acid/Bronsted Acid Alkylations of Carbonyl Compounds The previous investigations of the F-C alkylation of chiral alkylating agents by electron-rich arenes have thus provided a huge role historically in understanding the fundamental mechanistic complexicities of achieving high levels of both regiocontrol and stereocontrol. A selected historical evolution of key F-C asymmetric bond homologation of arenes with electrophiles other than alkylating agents under conditions of chiral catalysis will next be presented. Several interesting review articles45'46 have recently appeared on this subject. Fine-tuning of the substrate and reaction conditions is also critical for the asymmetric F-C alkylation of electron-rich aromatic compounds with functionalized aldehydes, ketones and imines. Both the regioselectivity and enantioselectivity of these alkylation reactions can be mediated through use of a complexing chiral catalyst. The catalyst may be either a Lewis or Bransted base.

Name Reactions for Carbocyclic Ring Formations

624 OH

O

(-)-menthol Et2AICI (100mol%)

OH H

,OH CCI3

H^CCI3 79

78

80, 55% (80%ee)

TS

In 1985, Casiraghi reported the asymmetric or/Zzo-hydroxylation of substituted phenols such as 78, an electron-rich arene, with chloral 79 in the presence of a chiral alkoxyaluminum chloride, prepared from stoichiometric amounts of EÌ2A1C1 and a readily available chiral alcohol (-)-menthol, afforded the corresponding chiral (7?)-trichlorobenzylic alcohol 80 in 55% yield and 80% ee.47 A clear limitation of this reaction was the requirement of a stoichiometric amount of the catalyst. The proposed stereoinduction model was explained via a chelated 1,5-complex of the chiral Lewis acid with the phenol oxygen and the carbonyl of the aldehyde substrate.

X O

81

^O02R (82a, R=Et) (82b, R=Me)

ZrCI, 5 mol% catalyst DCM, -10 °C

83a, R=Et, 56% (84% ee) 83b, R=Me, 59%

An interesting asymmetric addition of 1-napthol 81 to pyruvic esters 82 using a catalytic amount of a chiral {1R,4S,VR,4'S) dibornacyclopentadienylzirconocene Lewis acid was reported by Erker in 1990. Treatment of 1napthol (81, 1 equiv) to pyruvic esters (82a and 82b, 5 equiv) using 5 mol % of ZrCb-dibornacyclopentadienyl catalyst complex at -10 °C in DCM and water (27 mol %) afforded the corresponding substituted a-hydroxy esters 83a and 83b, respectively, in yields of 56-59%. The reported optical purity of 83a (84-89% ee) depended on the conversion of 82a (70-90%). The presence of a small amount of water appeared to increase the enantioselectivity of the reaction on the order of 10% ee, even though it was

Chapter 6 Transformations of Carbocycles

625

reported the catalyst gradually loses the chiral dibornacyclopentadienyl ligand to form an achiral catalytically active species. A bidentate interaction of the phenol hydroxyl and the carbonyl moiety was speculated to be the cause of the exclusive or//zo-selectivity. The optical purity of 83b (prepared in 59% yield from 82b) was not provided. This chiral catalyst was prepared efficiently in just a few steps from (+)-camphor.

0^ T r O'Pr X)' sO'Pr

RO 84a (R=Me) 84b(R="Bu)

85

10mol%86, DCM, 0 °C BINOL phenol activator (a,b; R=Me, "Bu) 87a (R=Me; 89%, 90% ee) para:ortho selectivity, 4:1 87b (R="Bu; 90%, 90% ee) para.ortho selectivity, 8:1

In 2000, Mikami reported the asymmetric addition of phenyl ethers 84a/84b to fluoral (85) using 10 mol % of catalyst Ti(0'Pr)2-6,6'-(i?,^-Br2BINOL 86 with 1:1 addition of matched 6,6'-(i?)-Br2-BINOL biphenol activator (Brensted acid of 86) to afford the corresponding (i?)-l-aryl-2,2,2trifluoromethyl alcohols 87a/87b in 89-90% yield and 90% ee49 The para/ortho-selectivity varied from 4 : 1 to 8 : 1 with just a simple change of R = Me to R = "Bu, demonstrating another complication in achieving complete selective regiochemical control. The jcara-selectivity suggests that co-complexation of the phenol oxygen of the arene and carbonyl moiety of the substrate with the Lewis acid does not play a significant role in the stereoinduction model. It is interesting that the enantioselectivity of 87a/87b was reduced ~ 10% to 79% and 83%, respectively, without addition of the 6,6'-(/?,i?j-Br2-BrNOL Bronsted acid coactivator (bisphenol Bransted acid precursor of 86). Incorporation of the electron-withdrawing 6,6'-Br2 substituents in place of hydrogen into the BINOL scaffold increased Lewis acidity of the catalyst. This proved to be a major factor in optimizing the enantioselectivity of the reaction (results not provided) by modulation of the reactivity of the catalyst. C Control of Indole Polyalkylation Side Reaction in the Asymmetric Alkylation of Indoles with Carbonyl Compounds (Section B, Part 1) and Imines (Subsequent Section B, Part 2)

626

Name Reactions for Carbocyclic Ring Formations

LA. \

Y

(Y=0, NR')

XI -H,X

XIII

XII

In the asymmetric alkylation of electron-rich heterocycles such as indoles with aldehydes, ketones and the corresponding imines under conditions of homogeneous and heterogeneous catalysis, additional regiochemical complications can arise such as polyalkylation.46,50 For example, the regioselective C-3 alkylation of indoles of type X produces an unstable C-3 aminomethyl or hydroxymethyl alkylated product (XI) which can eliminate H2X, creating another electrophile XII which alkylates again to produce the bisindolylmethylene alkylated product of type XIII. The reactivity of these side reactions can be modulated through the judicious matching of reaction conditions with a suitably reactive complexing bulky chiral catalyst. Choice of solvent can play a critical role in the formation or minimization of this side product. The byproduct can be favored under polar protic solvent conditions and can be a significant issue in lowering yield under Bronsted acid catalysis. Dong (2007) has recently extended this reaction to 5-substituted indoles of type 88 using glyoxal as substrate in the presence of 10 mol % of Ti(0'Pr)2-(5)-BINOL (90) in Et20 to afford the corresponding 3-substituted OS)-a-hydroxyester indoles of type 89 in 64-88% yield and 62-96% ee.5] As expected, electron-releasing substituents on the Ri position of the nucleus gave the best overall results in terms of yield and enantioselectivity of the reaction (results not provided). The choice of ether as solvent at < 0 °C was important in minimizing formation of the bisindolylmethylene ester alkylated side adduci of type 91.

Chapter 6 Transformations of Carbocycles

627

O.jro'Pr Oy N0'Pr

R

R

10mol%90,

'OCV **A -N R3

C0 2 Et

Et 2 0, <0 °C 89 (64-88%, 62-96% ee)

88 RaN.

R-i R-i Formation 91 Minimized

j

(1:1 glyoxal:90)

Ar-H (S/')-bottom face

The proposed Sz-face stereoinduction model involves stabilization of the Lewis acid-carbonyl complex with a formyl //-bond to the BINOL ether oxygen (1:1 complex of ethyl glyoxal:90). Replacement of the formyl hydrogen with an alkyl group provided little of the expected product with the bisindolyl alkylated side adduct (91) predominating and minimal stereocontrol for the associated adduct (not shown in scheme, ~ 10% ee).

Name Reactions for Carbocyclic Ring Formations

628

1 T /

R

° H

Me2N 93a-d (R= H, Me, CI, OMe)

C0 2 Et 89 (5 eq.)

MeO

X 95

F3C

92i, R= 'Bu 92ii, R= Bn 92iii R ='Pr 92iv ,R =Ph

H

Me2N 94a-d (19-72%, 81-95% ee)

MeO

H

,νΟΗ

'~ 5 =ir / ^C0 2 Et MeO

C0 2 Et 96

10mol%92i, THF

10mol%92i, DCM or THF

O

MeO'

R

bu (ii) '■T f d pTf *

97 (56%, 86% ee)

3Z In 2000, Jorgenson.52 reported the catalytic asymmetric addition of electron-rich arenes to glyoxylates and trifluoromethylpyruvates using 10 mol % 0S)-Cu(OTf)2-'Bu-BOX catalyst (92i), one of a number chiral cationic Cu bisoxazoline (BOX) bistriflate complexes developed by Evans, which has been recently reviewed (some examples shown in scheme, 92i-iv, [CuBOX](X)2).53a'b Treatment of unsubstituted (93a) or 3-substituted anilines containing activating or deactivating groups (93b-d; R = H, Me, halo, OMe) to ethyl glyoxylate (89) using 10 mol % Cu(OTf)2-'Bu-BOX catalyst (921) gave the corresponding (S)-chiral hydroxyesters 94a-d in 19—72% yield and 81-95%) ee. The lowest yield (19%>) was obtained with 94d, containing the most electron-releasing substituent (OMe). Under the same conditions, treatment of 1,3-dimethoxybenzene (95) with ethyl trifluoropyruvate (96) as the electrophile, gave a 56%> yield of the (5)-hydroxyester 97 in 86% ee. Using almost identical reaction conditions, Jorgenson (2001) explored the scope of the reaction of trifluoroethyl pyruvate (96) with other electronrich heterocycles, such as furans (98a/98b), thiophene (98c), and pyrroles (98d,f), to afford the corresponding 2-substituted (5)-a-hydroxyester heterocycles (99a-f) in 15-80% yield and 79-89%> ee.54 Treatment of unsubstituted, 2- and 4-substituted indoles 100a-e with 96 gave the corresponding (5)-3-substituted indolyl cc-hydroxy esters 101a-€ in 61-94% yields and 83-94%> ee. Substitution of the heterocyclic scafffold did not affect stereocontrol but greatly influenced regiocontrol.

Chapter 6 Transformations of Carbocycles 10mol%92i, DCM or THF

O

98a/b (R^H/Me, X=0) 98c (R^Me, X=S) 98d/e (R1=H/X=NH,NMe 98f (R1=COMe/X=NMe

F3C

X 96

629

/7-Λ

C0 2 Et

X

X

C02Et

99a/b (15/65%, 81/93% ee) 99c (16%, 79% ee) 99d/e (80%/42%, 83/93% ee 99f (69%, 89% ee) R4 F 3 C

10mol% 92i, DCM or THF

O

CF 3

R —H \\—l..*OH

*-

N R5 F3C C02Et 100a (R4,R5,R6=H,H,H) 100b (R4,R5,R6=H,Me,H) 96 100c (R4=CI,R5,R6=H,H) 100d (R4,R5=H,H,R6=Me 100e (R4,R5=H,H,R6=Ph

\ ) ~N\

*·

K

5

C 2B R6

°

101a (93%, 83% ee) 101b (94%, 89% ee) 101c (70%, 89% ee) 101d (88%, 94% ee) 101 e (61%, 87% ee)

Considerably lower yields were observed in formation of heterocycles of type 99 lacking a 5-methyl substituent (2-position of precursors 98, compare furans 98a/98b vs. pyrroles 98d/98f in respective yields of 15%/65% and 42%/69%), presumably due to a competitive 2,5-dialkylation pathway. Replacement of the pyrrole N-H moiety of 98d with an JV-Me moiety (98e), resulted in a substantial yield decrease of 99d and 99e, respectively (from 80% to 42%). This trend was not observed with the indole scaffold (101a vs 101b obtained in 93-94%) yield from 100a/b, respectively) perhaps due to a greater distance of the substituent from the reacting center. A reduction in yield (70% vs. 93%) with improved stereocontrol (89% vs. 83%o ee) was observed 4-C1 indole substitution (compare 101c vs 101a). Comparison of effects of 2-substitution show amelioration of yield with 2phenyl substitution (61% vs. 93% of lOle vs. 101a, respectively) with no significant effect on stereocontrol (87% ee vs. 83% ee).54

• 0 "~TV°\ (S/)-Bottom Face TrrrHPI

R

Ubi

Proposed Binding Model

The originally proposed binding model is consistent with coordination of the divalent copper complex to the 1,2-dicarbonyl moieties in bidentate fashion, making a square planar copper intermediate resulting in

630

Name Reactions for Carbocyclic Ring Formations

the shielding of the 7?e-face of the carbonyl moiety by the ter/-butyl substiruent. When the R group does not contain π-bond (sp3 hybridized), Siface 1,2-attack of the α-keto carbonyl moiety is the major alkylation pathway forming the chiral (5)-a-hydroxy ester, otherwise conjugare 1,4-addition occurs instead (see section E for examples of asymmetric 1,4-Michael additions).54 This catalyst system is well designed to have an excellent coordinating metal and easily tunable BOX ligand. Among the divalent ions in the first transition series, Cu(II) forms the most stable ligand-metal complexes (Mn < Fe < Co < Ni < Cu > Zn) acccording to the IrvingWilliams series rankings. The BOX catalysts are of type [Cu-BOX](X)2, where X is a weak or noncoordinating ligand (ΟΤΓ or SbFe"), and coordination of a bidentate substrate is thus favored in the equatorial plane. Jahn-Teller distortion in the a complex elongates the remaining apical sites where X may or may not reside promoting a very fast X ligand exchange rate. Thus the binding geometry can vary with substrate and nature of BOX ligand.530 The use of chiral Bransted acids (organocatalyst class) in asymmetric F-C reactions has been extensively reviewed.55 They can be used instead of oxophilic chiral Lewis acids for the asymmetric coupling of indoles to less reactive ketone substrates such as trihalopyruvates. The use by Mikami (2000)49 of a chiral phenol cocatalyst in boosting enantioselectivity (~ 10%) perhaps provided the first clue to such a possibility.

WTr \

^ 104

+

o F3C

X

96

5mol%102/3, Et 2 0, -8°C *R.,=5-OMe, Me, halo, C02Et and C02Me

105 via cinchonidine-102 (96-99%, 83-95% ee) HO ^CF3 C02Et

106 via cinchonine-103

(96-99%, 83-92% ee)

Török (2005) reported the use of chiral cinchona alkaloid Bransted acid organocatalysts (5 mol %), cinchonidine (102) and cinchonine (103), in the

Chapter 6 Transformations of Carbocycles

631

enantioselective addition of 5-substituted indoles of type 104 (where Ri = OMe, Me, halo, C0 2 Me) to ethyl 3,3,3-trifluoropyruvate 96 to afford the corresponding (S)- and (/?)-3-indolyl hydroxy esters, 105 and 106, respectively, in 96-99% yield and 83-95%
Part 2. Chiral Lewis Acid/Brensted Acid Alkylations oflmines Ts%

\ N H (104a), R1=H (104b), R1=OMe (104c), R1=Br (104d), R1=C02Me (104e), R 1 =N0 2

H

1-5mol%108 THF, -78 °C (To/ = p-tolyl)

N

TsHNl·

C0 2 Et 107

109a-e (67-89%, 78-97% ee)

- p \-Tol Tol

PF6

Lectka Cafa/ysM 08 Ts„

R:

C0 2 Et

A,C0 Et

H'

5mol%108inTHF, -78°Cto-10°C

2

(Ts = p-tolylsufonyl)

(110a)X=NMe, R2=H 107 (110b) X=NH, R2=H (110c) X=NH, R2=COMe

NHTs

V

^C02Et

111a (49%, 84% ee) NHTs C0 2 Et 112a (40%, 56% ee) 112b (not formed) 112c (76%, 94% ee)

The first general method for the asymmetric aza-F-C alkylation of a wide variety electron-rich heterocycles with electron-deficient aldimines using the chiral Lectka catalyst was first reported by Johannsen (1999),57a but later modified by Jorgenson (2000-2002) to improve synthetic practicality

632

Name Reactions for Carbocyclic Ring Formations

and scope.57b'c Johannsen57a reported that treatment of a variety of a 5substituted indoles (104a-e) with JV-Ts imines of glyoxylic esters (107) in THF at -78 °C, catalyzed by 1-5 mol % Lectka catalyst (108), (i?)-bis[2,2'di-p-tolylphosphanyl)-l,l'-napthyl-CuPF6 complex, gave the unnatural (R)amino acid esters 109a-e in good yield (67-89%) and enantiomeric purity (78-97% ee). The parent indole as well as electron-releasing and electronwithdrawing groups substituted on the 5-position (104a-d; R = H, OMe, bromo, CC^Me) were well tolerated with the expected adducts (109a-d) formed in very good yield (67-89%) and optical purity (88-97% ee), except in the case where R = N0 2 (109e from 104e, 71% yield, 78% ee). The majority of the products could be obtained enantiomerically pure through use of a single recrystallization. The reaction with pyruvate 107 was extended to N-methyl pyrrole (110a where R2 = H) as substrate but was not regioselective, affording 49% (84% ee) of the 2-substituted product (Ilia) and 40% yield (56% ee) of the 3-substituted pyrrole adduct (112a). None of the desired adduct (112b) was formed with iV-1-unsubstituted pyrrole (110b), the free NH forming an aminal with imine 107 instead (product not shown). The reaction of 2-acetyl pyrrole (110c), however, gave none of the 5-substituted analogue (111c), affording instead the 4-substituted adduct (112c) in 76% yield and 94% ee.51a "generalized" Ar-H (1.2-2.0 eq.) Λ

R„ +

H

N A

C

°2B

10mol%108, -78 °C MOCorCBZ 9:1 Toluene/DCM HN. S^C0 2 Et (To/ = p-tolyl) Ar

113a (e- rich benzenes) 114 (R=MOC) 113b (furans and thiophenes) 115 (R=CBZ) 113c (N-alkyl pyrrole) 116 (R=BOC) N(CH3)2

Ó

Me,a OMeb

Ó

117a (44-88%, 52-98% ee) 117b (24-82%, 72-94% ee) 117c (55%, 59% ee)

6

OMe /

U^

MOC x MOC MOC. / k ^N^C02Et N'^^C0 2 Et ^N^C02Et N CO,Et H H H H a 118) 68% (93% ee) 119)59%(89%ee) 121) 75% (94% ee) 122) 56% (97% ee) 120)63%(96%ee)b CBZ

Jorgenson (2000-2002) demonstrated the effective coupling of a host arenes and heteroarenes (113a-c) with 7Y-MOC and N-CBZ carbamateprotected-aldiminoesters (114 and 115, respectively) in the presence of catalyst 108 (5-10%) to afford the corresponding 7/?-amino acid derivatives (117a-c) in good yield and optical purity (vide supra).57b'c The carbamate protected iminoesters (114-116) were chosen over the N-Ts analogues due to

Chapter 6 Transformations of Carbocycles

633

the ease of their removal in a subsequent 7V-deprotection step. A mixed solvent system (9:1 toluene/DCM) was employed to allow synthesis of iminoesters 114-116 via a aza-Wittig coupling sequence from the corresponding glyoxylate esters (not shown in scheme), followed by the F-C coupling all in one pot (for representative examples, see 118-122). The reported yields are for the overall one-pot reaction sequence.

The proposed stereoinduction model involves a para-tolyl ligand of the catalyst blocking the bottom »SV-face of the α-iminoester leaving the exposed top Äe-face open for reaction with the arene moiety. The coupling of 7V-MOC and 7V-CBZ analogues 114-115 gave predictable high enantioselectivity. Coupling of the N-BOC moiety (116) occurred in modest yields but suffered from poor stereoselectivity leading to either the (R) or (5)-enantiomer (< 60% ee) of 117, depending on reaction conditions. This result was predictable based on modelling (density functional theory—(DFT) minimization calculations) of the catalyst complexes with 114 and 116. Poorer facial discrimination of the larger fér/-butyl moiety of 116 versus the methyl moiety of 114 was predicted due to greater steric crowding on the Re-face. Terada in 2004 explored the coupling of 2-methoxy substituted furan 123 with electron-rich and electron-poor JV-BOC aryl aldimines 124a-j in the presence of 2 mol % binapthol phosphoric acid (i?)-125, a chiral Brensted acid, to afford adducts 126a-j in high yield (80-96%) and optical purity (8697%>). This reaction was performed on gram scale using even lower catalyst loading (0.5 mol %) with the added benefit the catalyst could be easily recovered and reused. The researchers demonstrated the synthetic utility of

634

Name Reactions for Carbocyclic Ring Formations

the transformation by elaborating the furan product 126b to ^butenolide 127b via a high-yielding two-step sequence (sequence not shown). B0C

MeO

-N

HN

2mol%(/?)-125

MeO-

DCE, -35 °C 123

124a-j

BOC

127b (85:15 Syn/Anti) 2-steps via 126b (86% yield)

07N 128 (2 equiv.)

Ar

Product (Ar) %Yield. (% ee) 126a (4-OMePh) 95%, 96% ee) 126b (Ph) 95%, 97% ee) 126c (o-MePh) 84%, 94% ee) 126d (m-MePh) 80%, 94% ee) 126e (p-MePh) 96%, 97% ee) 126f (o-BrPh) 85%, 9 1 % ee) 126g (m-BrPh) 89%, 96% ee) 126h (p-BrPh) 86%, 96% ee) (R)-125 126i (2-napthyl) 93%, 96% ee) 94%, 86% ee) (Ar' = 2,4,6-('Pr)3C6H2) 126j (2-furyl)

R R

\

-BOC

PU'("> 'R TfO OTf R

10mol%92i-iv[5mol% excess Cu(OTf)2 Ligand] H »· DCM, 4A MS, 3-5 day (*5:1 eq. 122/123 used) Catalyst 92ii (R=Bn)* 92ii (R=Bn) 92iii(R='Pr) 92iv (R= Ph) 92i (R='Bu) 92ii (R=Bn)

129 Y=Ts

130 Y=Ph

Product %Yield. (% ee) 131 (Y=Ts)* 95%, 95% ee)* 131 72%, 95% ee) 131 50%, 32% ee) 131 39%, 0%ee) 131 33%, -6%ee) 65%, 0%ee) 132

0 02Nk

Cu (II) Bn

(/?e)-Bottom Face Ar-H Proposed Binding Model of Complex 92Ü/129

days) using a 5:1 stoichiometry of indole 128 to imine 129. The coupling conditions involved the use of 10 mol % of (5)-Cu(OTf)2-Bn-BOX catalyst (92ii, R = Bn) at 25 °C in DCM and 4 À MS to afford a 95% yield of (5)-3indolylarylmethanamine 131 in 95% ee. Treatment of ./V-phenyl imine 130,

Chapter 6 Transformations of Carbocycles

635

the desulfonylated analogue of imine 129, to these same reaction conditions, gave only the racemic adduci 132 in 65% yield. With a decreased 2:1 stoichiometry of indole 128 to jV-arylsulfonyl aldimine 129, the adduci 131 was obtained in 72% yield with the same optical purity (95% ee). Under the same reaction conditions, poorer conversions (33-50% yield) and enantioselectivities were observed in the formation of 131 using other Cu+2 BOX bistriflate catalysts bearing larger isoxazoline ligand substituents (92iii, 92iv, and 92i, where R = 'Pr, Ph, and 'Bu, respectively) in place of catalyst 92ii (R = Bn). 59 The proposed binding model involves 1,3-coordination of the copper to the sulfonyl and imine heteroatoms resulting in the shielding of the Si-face (top face as shown) of the imine moiety of 129 by the benzyl substituent of 92ii and attack of the arene on the exposed ite-face (bottom face shown). The drop of enantioselectivity observed with catalysts 92iii/93iv/92i is presumably due to increased A'^-strain between the arene of the imine and the larger R group of the ligand bound to the catalyst resulting in twisting of the bound conformation.59 Using the optimized reaction conditions, a 5:1 stoichiometry of indole 128 with iY-nosyl arylaldimine 133a-d, the electronic effects of the imine moiety on yield and enantioselectivity on the formation of the corresponding adducts (134a-d) was next examined. The N-nosyl protecting group was chosen due to ease of removal in a subsequent deprotection step. The effect of 4-substituention on the reaction was marginal as imines 133a-c (where R = H, Me, F) gave comparable yields (68-86%) and enantioselectivities (9294% ee) of 134a-c. A lower yield (47%) of 134d (R = OMe, strong electrondonating group) was observed, but with comparable enantiocontrol (88% ee).

^ N s 10mol%92ii[5mol% N excess Cu(OTf)2 Ligand]

N

\

~\\

JJ

K ^ ««WC · \ . . , , .. 128(5equ,v.) 133a-d

DCM,25°C,

4Ä MS, 3-5 day

Product %Yield. (% ee) 134a (R=H) 86%, 9 4 % ^ 134b (R= Me) 84%, 94% ee) 134c (R= F) 68%, 92% ee) 134d (R= OMe) 47%, 88% ee)

The reaction proved to be remarkably tolerant of substitution on the indole scaffold. Further exploration of indole substituents will not be shown in the scheme but will be discussed. Comparison of the coupling of a 5-OMe analogue versus the unsubstituted analogue of indole 128 with unsubstituted imine 133a (R = H) afforded similar results as the 5-OMe analogue of 133a was obtained in 92% yield (94% ee). Introduction of a 5-Br substituent into

636

Name Reactions for Carbocyclic Ring Formations

128, however, lowered the yield (50%) and enantioselectivity (77% ee) in the coupling of 133a.59 The concept of tunable chiral thiourea based organocatalysts, useful for a wide variety of asymmetric reactions, was invented by Jacobsen in 1999 and has been extensively reviewed over the last few years.60 They have been particularly useful in the F-C alkylations of imines. In 2006,61 Deng discovered thiourea catalyst 135 to be an effective general catalyst in promoting effective asymmetric F-C reactions of substituted indoles (136) containing either electron-donating or withdrawing groups with aromatic or aliphatic JV-arylsulfonylimines (137 and 138 respectively) to afford the corresponding adducts 139 and 140 in very good yield (53-98%) and stereocontrol (83-96% ee).61 Treatment of a variety of a 4-, 5- and 6substituted indoles (136) with 7V-Ts or N-Bs imines of aromatic imines (137) in EtOAc at 50 °C and 10 mol % thiourea organocatalyst 135 in EtOAc at 50 °C, gave the unnatural (5)-3-indolylarylmethanamine 139 in 86-98% yield and 86-98% ee. Remarkably, the reaction of indole (128) with aliphatic JV-TS imines 138 under the same reaction conditions promoted formation of the corresponding indolylalkylmethanamine 140 in 53-86% yield and 94-96% ee. Since Jorgensen57 and Zhou's comparable methods59 are limited to use of more activated imine substrates such as aromatic imine and imine esters, this method has proven to be more versatile in terms of scope. The mechanism of activation of thiourea organocatalysis will be presented in greater scope in the next section.

136 (2 equiv.;

137 (1 equiv.)

R = 4-CI, 3-OMe, 2-Br, 4-CF3, 4-Me, H R-, = 6-CI, 6-Br, 6-OMe 5-Me, 4-OMe

139 86-98% (86-96% ee)

Chapter 6 Transformations of Carbocycles

637 Ts

fx\

H

128 (2 equiv.)

HN,

*

N

A 138 (1 equiv.)

10mol%135 EtOAc, -25-50 °C, R2 = cyclohexyl, 'Pr 'Bu, n-Bu at 50 °C R2 = BnOCH2 at -25 °C

- U ΓΥΛ V

H 140 53-86% (94-96% ee)

The use of aliphatic imines in aza-Friedel-Crafts reactions has been limited by stability to the reaction conditions, particularly with enecarbamates or enamides. Terada (2007)62 demonstrated that substituted indoles of type 136 containing either electron-donating or electronwithdrawing groups at the 5- or 6-positions could be reacted with E- or Z-NBoc-protected enecarbamates 141 in the presence of 5 mol % (7?)-BINOLphosphoric acid (chiral Bronsted acid 125) in CH3CN at 0 °C to afford the Friedel-Crafts adducts 142 in 63-98% yield and 90-94% ee. The (Z> and (£)-enecarbamates of 141 afforded adducts 142 in identical enantioselectivities but with different rates. It was speculated that the ratedetermining step involved formation of a common imine intermediate by protonation of the enecarbamates by the phosphoric acid catalyst. In addition, a strong solvent effect was observed with polar protophobic solvent shown to greatly improve catalytic efficiency. Similar methodology for asymmetric construction of quaternary asymmetric centers was introduced by Zhou in 2007.63a'b Treatment of oc-aryl enamides 143 with indole 136 in the presence of 10 mol % (5)-BINOLphosphoric acid catalyst 125 gave the resulting Friedel-Crafts adducts 144 in 73-97% yield and 73-97% ee. Presumably, isomerization of enamine 143 to imine 143a under the influence of the catalyst occurred before alkylation by indole 136. Alkylation of either of the free JV-H moieties of the indole and/or enamide led to a complete loss of reactivity. This finding supports the proposed stereoinduction model where chiral phosphoric acid catalyst 125 activates both the indole and ketamine (143a) via two //-bonding interactions of the trimolecular complex 136/143/125. The protonation of ketimine 143a, formed by isomerization of enamide 143, then activates it for nucleophilic attack of the indole on the Re-face, resulting in the observed adduct 144.

Name Reactions for Carbocyclic Ring Formations

638

H

R2

BOC^ARi

(141) CH3CN, 0 °C

5 mol% (R)-125 Ar'

142 63-98% (90-94% ee) R,, R2 = H, alkyl, aryl

R-r

NHAc

136(1 equiv.) Ar'Catalysts

25

10mol%(S)-125 4A MS, PhMe, Temp 144 AcHN^ 73-97% (73-97% ee)

ZW-CPrhCeHz) Temp =0°C or RT (majority cases)

(143)1 Ar

Re-face (Top Face) Attack of 136 on 143a Ar"

N A AJL I N ^

Ar

H 143

_~ A A A ™

=^^

Ar

N N

^

O' %

-—

143a

v<

Me S

Ar Proposed Model \.\-^ Complex 136/143a/125 R

D

Asymmetrie Pictet-Spengler and Related N-Acyliminium Cyclizations R-iCHO »Bronsted Acid (145)

N-H

(146)

(147)

The Pictet-Spengler reaction is an important reaction involving condensation of an unsubstituted or substituted tryptamine 145 with an aldehyde RiCHO, usually in the presence of a Bronsted acid to afford an iminium ion 146 which undergoes intramolecular cyclization to afford biologically important tetrahydro-ß-carboline (147). Although the cyclization affords the C-2 adduct, the initial F-C product is the spirocyclic C-3 adduct, which

Chapter 6 Transformations of Carbocycles

639

undergoes rearrangement to the more stable C-2 adduct (not shown). In addition other related analogues may be also be accessed such as the tetrahydroisoquinoline scaffolds (not shown). In this section, discussion of the asymmetric Pictet-Spengler reaction will be limited to iminium ion and related cyclizations using Lewis and Bransted acid chiral catalysts. N-OH

N-OH

CH2CI2, -78 °C 2eq. of(+)-lpc2BCI(149)

(1 equiv. of 148) 148a 148b 148c 148d 148e

R, Ri Ri Ri Ri

(150)

=Ph = 4-OMePh = 1-Napthyl =Me = 'Bu

,BCI

(149)

2

150a 150b 150c 150d 150e

R1 = Ph (92%, 75% ee) R·, = 4-OMePh (65%, 90% ee) R, = 1-Napthyl (94%, 86% ee) Ri = Me (91%, 43% ee) R, = fBu (75%, 35% ee)

Nakagawa and co-workers in 1996, investigated the first asymmetric Pictet-Spengler reaction of ./Vi-hydroxytryptamines (nitrone analogues 148ae) using a super stoichiometric amount (2 equiv) of a chiral Lewis acid (diisopinylcampheyl-chloroborane, Ipc2BCl, 149) to afford the corresponding (S)-M>-hydroxytetrahydro-ß-carbolines (150a-e) in 75-94% yield and 3590% ee.65 Good yields (65-94%) and enantiomeric purity (75-90% ee) were observed when Ri was aromatic (150a-c via 148a-c), however, poor stereocontrol was observed when Ri was aliphatic (150d,e in 35%^13% ee via 148d,e). The requirement of a superstoichiometric amount of the chiral catalyst is the likely result of catalyst inhibition by the Lewis basic product. 1)R,CHO(1.05eq.) 3A MS or Na 2 S0 4 2)AcCI(1.0eq.) R 2,6-lutidine (1 eq.) 3) Cat. 151 (5-10 mol%) r^f Et 2 0, Temp

145(1 eq.)

*-

NAc

Several Steps

154-(+)-Yohimbine via 153d

153a-g

s H

w //

Ph

Catalyst 151 R2/R3='Bu, Catalyst 152 R2/R3=Me, n-C5Hu

153a-g R 153a) H 153b) H 153c) H H 153d) 153e) H 153f) 5-OMe 153g) 6-OMe

Temp -30 °C -40 °C -60 °C ^5Η11 (CH2)2OTBDPS -60 °C /Bu -60 °C -40 °C CH(Et)2 CH(Et)2 -40 °C Si CH(Et)2 CH(Me)2

%Yield, (% ee> 65%, (93% ee) 67%, (85% ee) 65%, (95% ee) 77%, (90% ee) 75%, (93% ee) 81%, (93% ee) 76%, (86% ee)

Greater success has been achieved with chiral Bronsted acid or chiral hydrogen bond donor-catalyzed Pictet-Spengler-type reactions involving the

Name Reactions for Carbocyclic Ring Formations

640

use of N-acyliminium or jV-sulfenyliminium ions as the electrophilic component. The use of tunable thiourea organocatalysts (i.e., 151 or 152), championed by Jacobsen has played a key role.60 Jacobsen in 2004 published an enantioselective one-pot three-step method for the synthesis of intermediates for indole alkaloids, tetrahydro-ß-carbolines (153a-g), involving a Pictet-Spengler iV-acyliminium ion-cyclization reaction as the key step.66a The key TV-acyliminium ion-intermediate is formed via a two-step dehydration-acylation sequence: starting from tryptamine 145 (1.0 equiv) and aliphatic aldehyde RiCHO (1.05 equiv), then cyclized using 5-10 mol % of Jacobsen's thiourea catalyst 151 in Et20 at low temperature to generate the corresponding (5)-tetrahydro-ß-carbolines (153a-g) in 65-81% yield and 8593% ee. There was no significant amelioration of yield or optical purity with methoxy substitution at the the 5- or 6-positions when R] was aliphatic (compare 153f,g versus 153a) Jacobsen completed the enantioselective total synthesis of the indole alkaloid (+)-yohimbine (154) from chiral tetrahydroß-carboline intermediate 153d in 2008.66b Ο ί Λ 1)NaBH4/MeOH o rR Li T H F M_i i · ' ~ \ 2) Cat.152 (10 mol%) TMSCI, TBME, R ^ (2eq.) T(°C) > # 24h-72h ^

r:

156a-g(X=R 1 ,OH, 1 eq.) 155a-g (X=0) (X!Y)

157a-g (63-92%, 91-98% ee) 157 a) b) cyclize c) d) e) f) g)

R H H H 5-Br 5-OMe 5-OMe H

i

1 1 2

&

H Me n-Bu H H Me Me

158 (+)-Hamicine via lactam 157a Terra -55 °C -78 °C -78 °C -55 °C -55 °C -78 °C -78 °C

%Yield. (% ee) 90%, (97% ee) 92%, (96% ee) 74%, (98% ee) 88%, (96% ee) 86%, (95% ee) 84%, (91% ee) 63%, (92% ee)

This methodology has been extended to other related types of Nacylimminium ion cyclizations. No specific thiourea catalyst has been found to work for all transformations within this class. Hence each specific reaction must be carefully screened. Jacobsen and co-workers (2007) have also shown that y-hydroxy-2-pyrrolidinones or y-hydroxy-2-piperidinone 3-substituted indoles (156a-g) activated by use of 2 equiv TMSCI as dehydrating agent in the presence of 10 mol % of Jacobsen chiral thiourea organocatalyst 152 in TBME, can undergo asymmetric Pictet-Spengler cyclization to afford either indolizidinones or quinazolidinones (157a-g) in high yield (63-92%) and

Chapter 6 Transformations of Carbocycles

641

enantiomeric purity (63-98% ee). The effect of indole substituents on the cyclization reaction was next investigated.67 Substitution at the 5-, 6- and 7-position of indole 156 with either electron-donating or withdrawing groups was also well tolerated (6- and 7substitution results are not shown in scheme). The reaction of unsubstituted and 5-substituted indole hydroxylactams, 156a-g, gave the corresponding chiral indolizidinones 157a-f in 74-92% yield and 91-98% ee, regardless of the electronics of substitution. Increase of the size of the Ri moiety had little effect on yield and stereocontrol (see 157a-c). The reaction of γhydroxypiperidine (156g) fared equally well, affording quinazolidinone 157g in 63% yield and 92% ee. The key γ-hydroxylactam precursors (156a-g) were prepared by a two-step sequence involving condensation of the corresponding tryptamines 145 with succinic anhydride or glutaric anhydride in toluene/AcOH (tryptamine condensation step with corresponding anhydrides not shown in Scheme), followed by NaBrLi/MeOH or organolithium mediated addition to the carbonyl of the resulting intermediate imides 155a-g. The enantioselective total synthesis of the indole alkaloid (+)-hamicine (158) was accomplished in just four steps in 60% overall yield from tryptamine 145a. The final step of the synthesis involved a L1AIH4 amide reduction of indolizidinone 157a to afford (+)-hamicine (158) in impressive 95% yield.67 Method A Method B (R=H, Me, OMe) (R=Halogen) 5mol%160 10mol%160 TMSCI(2eq.) or BCI 3 (10mol%) H2Q (8 mol%) TBME (0.12M), -30 °C (1 equiv) 128 (R = H) 136 (R = Sub.)

AcO (1 equiv) 159i(n=1) 159Π (n=2)

Method A: 161a-f 70-93% (80-94% ee) Method §2 161g-k 47-81% (92-97% ee)

cx ^ Γι" Γ^ s

JV

f^\

^sj

N

A YÄ ^ N H N H -V *

°

HO

N

^H

\^T

/ ) Et3Si^Vj/

,

'

^

\ς

Jacobsen Catalyst 160

""

161 a) b) c) d) e) f) g) h) i) j) k)

R H H 5-Me 5-Me 6-OMe 6-OMe 4-F 4-Br 5-Br 6-CI 6-CI

n 1 2 1 2 1 2 1 1 1 1 2

Method A A A A A A B B B B B

% Yield. <% ee' 90, (93% ee) 70, (93% ee) 79, (90% ee) 93, (94% ee) 80, (80% ee) 76, (88% ee) 57, (96% ee) 47, (97% ee) 80, (93% ee) 81, (96% ee) 40, (92% ee)

642

Name Reactions for Carbocyclic Ring Formations

It was proposed that the reactivity and catalytic mechanism for chiral H-bond catalysis stems from dual H-bonding interactions of the thiourea with the chloride of XIV promoting its loss to form reactive N-acyliminium ion (XV). Recently, Jacobsen and co-workers (2009) have explored the intermolecular version of this reaction.68 They have found that N-benzyl substituted Y-acetoxy-2-pyrrolidinones (159i) or y-acetoxy-2-piperidinones (159ii), activated by use of 2 equiv TMSC1 as dehydrating agent in the presence of 10 mol% of Jacobsen chiral thiourea catalyst 160 in TBME at -30 °C, can undergo asymmetric iV-acyliminium ion cyclization with unsubstituted (128) or electron-rich indoles (general formula 136) to afford either (R)-3 -substituted γ-substitued pyrrolidinones or piperidinones (general formula 161a-f) in good yield (70-93%) and enantiomeric purity (80-94% ee). No significant difference was observed in formation of pyrrolidinone versus piperidinone analogues was observed in yield or stereocontrol (161a,c,e, versus 161b,d,f, respectively). This method (A) worked well with indole 128 or indole analogues 136 with electron-donating groups at the 4-, 5-, and 6-positions (Me, vinyl or OMe, not all results shown in scheme). Less reactive halo-substituted indole analogues (electron-withdrawing groups typically gave poor conversion but high enantioselectivity, results not shown in scheme. Use of the oc-acetoxy lactam susbstrate for activation over the oc-hydroxy lactam was necessary due to the higher solubility of the corresponding iminium ion intermediate. Activation of 159i/159ii (n = 1 and n = 2 respectively) with 10 mol %> of BCI3 and treatment of the respective 4-, 5- and 6-halo substituted analogues of 136 (0.12 M in TBME) with 10 mol % 160, afforded the corresponding pyrrolidinone and piperidine analogies (161g-k) in 47—81 % yield and 9297% ee. Using this method (B), substantially higher yields were observed in the formation of pyrrolidinone versus piperidinone analogues (compare 6-C1 indole substitution affording yields of 161j/161k in yields of 81%) and 40%, respectively). The proposed catalytic mechanism accounting for the reactivity (methods A and B as well as the related intramolecular cyclizations) involves generation of a oc-chlorolactam intermediate 162 formed in situ from the corresponding α-acetoxylactam 159i/159ii which is trapped by indoles 128/136 through an SNl-type anion-binding mechanism. In method A, the synergistic effect of TMSC1 (2 equiv) and catalytic H2O (8 mol %>) suggests that α-acetoxylactam 159i reacts with HC1 generated in situ to form a key chlorolactam intermediate 162. Since the enantioselectivity depends on the chloride ion concentration, the chlorolactam is believed to be a key intermediate that reacts with indole (128 or 136) by a SNl-type anion binding

Chapter 6 Transformations of Carbocycles

643

mechanism via the intermediacy of the resulting jV-acyl iminium ion. Method B requires the use of more reactive BCI3 to generate the same intermediate.

Method A or

162

AC

° 159i/ii

R* + O

In 2008, Jacobsen reported a clever pyrrole asymmetric Pictet-Spengler like ./V-acyliminium cyclization strategy of 3-substituted ß-pyrroloethyl hydroxylactams 163 prepared via substituted succinimide precursor 164, allowing access to either chiral tricyclic pyrroloindolizidone (165-167) and pyrroloquinolizidine scaffolds (168, 169), depending on whether precursor 163 nitrogen is jV-protected.69 The key cyclization intermediates of general class 163 were prepared via reduction (NaBH4/MeOH) or organolithium addition (RLÌ/THF/-78 °C) of the carbonyl moiety of the corresponding ßpyrroloethyl succinamide and glutarimide precursors 164 (see Ref. 69). Cyclization of the JV-TIPS protected pyrrolohydroxylactam 163 (where « = 1 and Ri = alkyl, H), activated by 2 equiv TMSC1 in TBME at -55 °C to -30 °C, gave a racemic 1.5-3:1 mixture of the C-4 (165) versus C-2 cyclization product (168), regardless of whether Ri was substituted with H or alkyl. Cyclization at C-2 was unexpected since the TV-TIPS moiety effectively shields the N-\, C-2 and C-5 positions. Coaddition of 20 mol % of Jacobsen chiral thiourea catalyst 152 to 163 under the same reaction condition, afforded the desired C-4 adduci 168 in good yield (49-77%) and excellent enantiomeric purity (92-96% ee). Evidently co-complexation of the organocatalyst to the JV-acylimminium ion derived from 163, provided an effective discriminating spatial environment.

644

,JA

Name Reactions for Carbocyclic Ring Formations

O

1)NaBH 4 /MeOH orRìLi, THF

Ln / N ^ \ 2 ) C a t

152

* Η i2^

W

>

S

^ TIPS

N

( 2 0 mol% )

TMSCI, TBME,

C(4,

166 (n=2, 70-75%, 93-97% ee (Ri=Me, Bu)

/—'

iSc(2i L

-55°Cto-30°C

165 (n=1, 49-77%, 92-96% ee) (Ri=H, Me, "Pr, "Bu.'Bu, Ph)

1)NaBH 4 /MeOH orR^i.THF.^e«^

n-JiK. Λ 7

υ

/N~^

2 Cat 152 X

)

·

<20

mol%

(2eq) 78 c

AcCI, TBME,

-N/ R

)

- ° . fS

N R*1 H

pM63 ( X = R Ì , OH; R=H, TIPS) 168 (n=1, 51-86%, 88-93% ee) 164(X=0) (R 1= H, Me, "Pr, "Bu, 'Bu)

L

a

see rei. 69 for details

169 (n=2, 54-71 %, 52-65% ee) (Ri=H, Me, "Bu)

167 (n=2; R-,=H; 76%, 70% ee

Treatment of the ,/V-TIPS protected pyrrolohydroxylactams 163 (where n = 2, R = alkyl) gave equally good results (70-75% yield, 93-97% ee); however, replacement of Ri moiety with H gave a dramatic decrease in stereocontrol of 167 (76% yield, 70% ee).69 Cyclization of the unprotected NH pyrrolohydroxylactam 163 (where n = 1 and Ri = alkyl, H), activated by 2 equiv AcCI in TBME at -78 °C, gave the expected C-2 cyclized adduct 168 in 51-86% yield and 88-93% ee. Due to the higher reactivity of the C-2 cyclization mode, activation using AcCI at -78 °C proved sufficient. Treatment of JV-H pyrrolohydroxylactam 163 (n = 2, R = alkyl and H) to the same reaction conditions, gave good yields (54-71%)) of 169 but with considerably reduced stereocontrol (52-65%). The reason for this was not clear. These authors also showed that these C-2 and C-4 cyclized chiral pyrroloindolizidone and pyrroloquinolizidine scaffolds could be converted to many clever and highly functionalized chemotypes (transformation not shown in scheme).69' One practical limitation for implementation of these methods on pilot plant scale is the reliance of achieving high enantioselectivity of these reactions at very low temperatures (< -30 °C). A giant stride toward achieving goal this has recently been reported. In 2009, Jacobsen reinvestigated the asymmetric Pictet-Spengler reaction of 6-OMe substituted and unsubstituted tryptamines (type 145) with a wide variety of aromatic and aliphatic aldehydes (type RiCHO) in Toluene at room temperature using 20 mol % of a chiral thiourea organocatalyst (170a) in combination with a weak Bronsted acid, benzoic acid (20 mol %), to afford the tetrahydro-ß-carboline adducts 147a-g in excellent yield (45-94%) and enantiomeric purity (8595%) ee). Matching of the catalyst to the reaction again proved critical as Jacobsen catalyst 170a (R4 = 'Pr) proved superior to 170b (R4 = 'Bu), details not provided in scheme.70

Chapter 6 Transformations of Carbocycles

645

RiCHOCUOeq.) Cat. 170a (20 mol%) 20 mol% PhC02H Toluene, rt, 11 h-5d »"

l

145 (1 equiv.)

*(0 mol% PhC0 2 H added) *(Rx took 10 days)

147 a) b) R2 R4 s rf\ c) d) 3 e)** ^ H H f) 170a R2, R 3 =Me, Bn and R4='Pr f)* 170b R2, R 3 =Me, Bn and R 4 = f Bu g)* CF 3

R 6-OMe 6-OMe 6-OMe 6-OMe H 6-OMe 6-OMe 6-OMe

147a-g RT 4-OMe(Ph) Ph 4-Br(Ph) 2-Br(Ph) 2-Br(Ph) CH(Me) 2 CH(Me) 2 A7-pentvl

%Yield. i% eei 78%, (85% ee) 94%, (86% ee) 79%, (94% ee) 74%, (95% ee) 45%, (95% ee) 60%, (88% ee) 90%, (94% ee) 74%, (86% ee)

Bronsted acid H-X (BzOH)

•R-NAN-R* I

H

\

C(3)-C(2) RR step not shown

I

H

N:

R.,CHO

145 R^ Dehydration

146

As expected, the unsubstituted tryptamine 145 (where R = H) coupled with 2-bromobenzaldehyde afforded 147 in the lowest observed yield (45%, 10-day reaction) but maintained excellent stereocontrol (95%). Both 5- and 6-methoxy substituted tryptamines 145 coupled with electron-poor arene and aliphatic aldehydes in superior yield and optical purities (see 147c,d data). The combination of the reactive electron-rich 6-OMe substituted tryptamine 145 with either i-butyraldehyde or «-hexanal (highly reactive aliphatic aldehydes) required no weak Bronsted cocatalysis (none PhCC^H added) but

646

Name Reactions for Carbocyclic Ring Formations

longer reaction times (data not provided) and still providing the expected adducts 147f,g in a respectable 74-90% yield and 86-94% ee. The greater scope of this reaction was attributed to the dual cyclic Brensted acid/H-Bond donar cocatalysis mechanism. The catalytic cycle initially involves imine protonation by the chiral thiourea catalyst 170 associated via H-bonding to the conjugate base (X~) of a weak Brensted acid (H-X, benzoic acid in this case) additive. Intramolecular cyclization of the protonated iminium ion 146, followed by rearomatization regenerates the Brensted acid cocatlayst (benzoic acid).70a Note for brevity, the plausible rearrangement (RR) step of the inital C(3)-spiroalkylated adduci7 b to the final tetrahydrohydroisoquinoline scaffold 147 is not shown. Cat. (R)-125 (20 mol%) R.,CHO (1.10 eq.) C02Et Na2S04, Toluene, C02Et -10 o C a /-30°C b /-45 o C c 171 (1 equiv.)

Et02C R

172a-j %Yield. (%.ee) 76%, (88% ee) 96%, (90% ee) 94%, (86% ee) 90%, (87% ee) 96%, (80% ee) 64%, (94% ee) 82%, (62% ee) 60%, (80% ee) 40%, (89% ee) 98%, (96% ee)

Stronger H-bond donors such as chiral Brensted acids have also been used in the asymmetric Pictet-Spengler reaction. List (2007) has reported the chiral Brensted acid-catalyzed asymmetric Pictet-Spengler cyclization of conformationally biased unsubstituted, 5-, and 6-methoxy substituted tryptamines 171 with aliphatic and aromatic aldehydes RiCHO.71 The tryptamines 171 were conformationally conformationally biased by evocammo geminai diester mode of substitution (Thorpe-Ingold effect). Thus treatment of tryptamines 171 with aldehydes RiCHO in the presence of Na2SÜ4 dehydrating agent and 20 mol % of chiral (/?)-phosphoric acid catalyst (125) in toluene at low temperature (10 °C to -45 °C) afforded the corresponding gem diester substituted (/?)-ß-carbolines (172a-j) in 40-98% yield and 80-96% ee. Simple tryptamine, or phenethylamine-derived imines

Chapter 6 Transformations of Carbocycles

647

lacking gem disubstitution (i.e., 145) do not undergo cyclization, limiting the reaction scope. Instead, products are formed resulting from sequential homoaldol condensation and imine formation reactions (not shown). These known side reactions, observed with strong Bronsted acid-mediated Pictet-Spengler reactions of tryptamines with aliphatic aldehydes, can significantly lower the yield of the reaction. H NSC(Ph)3

1)Cat. 174(20mol%) F^CHO (3.0 equiv.) 3A MS, Toluene, 0 °C 20 mol% BHT, 2-24 h ». 2) PhSH, 4M HCI

173 (1 equiv.)

175a-h

1Z5 R

Ar' -H

0. P yL (R)-174 O xO "Ar' Ar' = 3,5-(CF3)2C6H3

a) b) c) d) e) f) 9) h)

Me n-pentyl 2-ethyl(Ph) Bn iPr cyclohexyl Ph Ph(4-N02)

%Yield. (% ee) 88%, (30% ee) 87%, (84% ee) 88%, (76% ee) 90%, (87% ee) 77%, (78% ee) 81%, (72% ee) 70%, (82% ee) 78%, (82% ee)

Hiemstra (2007) eliminated the competing enamine alkylation pathway by cyclization of unsubstituted TV-tritylsulfenyltryptamines 173 with aliphatic and aromatic aldehydes (RjCHO) in the presence (20 mol %) of a 79

related chiral phosphoric Bronsted acid catalyst (Ä)-174. The yields (7090%) and optical purities (30-87% ee) reported for (i?)-ß-carbolines hydrochlorides (175a-h) are for a one-pot operation that includes the PictetSpengler cyclization step and removal of the nitrogen protecting group. The key cyclization step involved treatment of tryptamine 173 (1 equiv) with either an aliphatic or aromatic aldehyde (3 equiv RiCHO), 3 Ä MS and 20 mol % BHT in toluene at 0 °C using 20 mol% of phosphoric acid catalyst R 174. The deprotection conditions involve treatment of the crude PictetSpengler adduct reaction mixture with 1.2 equiv thiophenol, followed by 4 M HCl/dioxanes to isolate the enantioenriched ß-carbolines (175a-h) as HCI salts. The addition of 3,5-di-(fer?-butyl)-4-hydroxytoluene (BHT) to the reaction mixture as a radical scavenger prevented loss of the 5-tritylsulfenyl TV-protecting group occurring via free-radical-mediated homolytic TV-S bond cleavage.

648

Name Reactions for Carbocyclic Ring Formations

E Asymmetric Friedel Crafts Michael-Type Alkylations using Chiral Lewis acids and Organocatalysts In section B, many examples reported by Jorgensen in 2001 of successful asymmetric 1,2-attack of electron-rich arenes onto the carbonyl moiety of an α-ketoester catalyzed by 5-10 mol % (5)-Cu(OTf)2-'Bu-BOX catalysts (92iiv) were shown. 'c During the same time period. Jorgensen also reported many examples of asymmetric thermodynamic conjugate addition of

JΒ ΰL

?

U

a ΒBu< υ

' πο"δπ ' (5-10 mol%)

Low T e m p '

<Bu' J

(Si>Bottom Face

Catalyst 92i

+

Kj

o

^

o

^ ~ \

0

R 1 ^^ A C0 2 R 2

176

R.

179

^ ^

(S/)-Bottom Face

2^2

"***/=/

CO2R2

Ri 1,4-Addition Model ("Asymetric Michael Addition")

Typical Conditions: Arene:170 (1.3:1-1:1) TempO°Cto-78°C Et 2 0 or DCM 5-10mol%X,

O M e R i ._. O I Λ"

C0 2 R 2

MeO 178 (65-68%, 60-89% ee)

C0 2 R 2

C0 2 R 2 (R-,=alkyl, aryl) (R2 =Me, Et)

177

Cu(ll) - ,

h 'Bu 0 / \ J Bu'

(R-palkyI, aryl) (R2 =Me, Et)

177

Ri

, I

Bu'

1,2-Addition Model (See Section 6.4.7.1.2)

.OMe

MeO.

, r T

U

180 (90-99%, 79-88% ee)

C0 2 R 2 N H 128 (R = H) 136 (R = Sub.)

R-i

^* 177

CO2R2

(R=alkyl, aryl, OMe, CI, C0 2 Me) (R^alkyl, aryl) (R2 =Me, Et)

181 (69-98%, 60-99.5% ee)

Chapter 6 Transformations of Carbocycles

649 OH Ri

u

O

C0 2 R 2 (183A) Bu

' TfO

v Bu OTf

(10mol%92i) i Et 2 0 (183B) (R=6,7,8-halo, 7-OMe, H) (R^alkyl, aryl and R2=Me, Et)

""Ri (45-98%, 78-92% ee)

ß-substituted α,β-unsaturated ketoesters (1,4-attack to the alkene), under virtually identical reaction conditions, via the same attack trajectory (vide supra).73 Thus the 1,4-addition of β,γ-unsaturated oc-keto esters (Ri = alkyl, aryl and R2 = Me, Et) with a wide variety of arene scaffolds (176, 179, and 128/136 respectively) using 5-10 mol % (5)-Cu(OTf)2-iBu-BOX catalyst (92 i) gave the corresponding (3S)-3-arylsubstituted Michael adducts 178,180 and 181 in good yield with moderate to excellent enantiocontrol (see above scheme). The following general observations are not shown in the scheme. The use of the aerobically stable (5)-Zn(OTf)2-iBu-BOX as catalyst gave comparable levels of stereocontrol to Cu(OTf)2-'Bu-BOX catalyst 92i. The use of α,β-unsaturated α-keto ethyl ester 177 (R2 = Et) versus a-keto methyl esters (R2 = Me) as Michael acceptors gave higher levels of stereocontrol. Enantiocontrol of substituted indole adducts (181) was remarkably intolerant of the electronics of substitution at the 5- and 6-positions (halogen, alkoxy, etc.).73 Jorgensen in 2003 applied this methodology to the synthesis of chiral 3substituted 4-hydroxycoumarins, important biologically active chemotypes as anticoagulant and antibiotics.743 Coupling of a variety of substituted 4hydroxycoumarins 182 with methyl/ethyl 3-alkyl and 3-phenyl substituted ocketoesters of type 177 in the presence of 10 mol % of 92i catalyst in Et 2 0, gave the corresponding Michael adduci (183A), which underwent intramolecular cyclization to exist primarily as tricycle 183B in 45-98% yield in 78-92% ee. A similar strategy enabled the total synthesis of Warfarin.740 Jorgensen (2001) also investigated the asymmetric alkylation of unsubstituted (128) or substituted indoles (136) with ß-aryl substitituted alkylidene malonates (184), under the same reaction conditions, but met with only modest success (< 70% ee achieved).75 Treatment of a wide variety of unsubstituted (128) or substitituted indoles 136 with ß-aryl substitituted alkylidene malonates (184) as the substrate with the same catalyst (10 mol %

650

Name Reactions for Carbocyclic Ring Formations

'TfÖ ÒTf (10mol%92i) 0 °C or 25 °C, THF \ Ar'^V'ORi *· N *Ar configuration H O^OR 1 is R-designation (184a, R! : Me) 128 (R = H) (RJ-185 General: 45-99%, 46-69% ee) 136 (R Sub.) (184b, Ri Et) (7?)-185a*(R = H, Ar = Ph, R2= C02Me) (95%, 50% ee) NaCI, Δ |—(R)-186b* (R = H, Ar = Ph, R2= C02Et) (R = 5-OMe, H, 4-CI) wet DMSO (73%, 60% ee) (Ar = Ph, 2 or 4-halo, 4-NO2) (74%) L ^ (7^.-187* (R = H,Ar=Ph, R2 = H)

of (6)-Cu(OTf)2-'Bu-BOX catalyst 92i) in THF at 0 °C gave the corresponding Michael adducts (185 in the ^-configuration, designated as (R)-185) in 45-99% yield and 46-69% ee. The reactions of methyl and ethylß-phenyl-substitituted alkylidene malonate esters (184a/184b, where Ar = Ph, Ri = Me and Et, respectively) with indole 128 under the reaction conditions afforded the methyl ester adduct (7?)-185a in higher yield (95%) but lower enantioselectivity (50% ee) than the corresponding ethyl ester (R)186b (73% yield, 60% ee). Subjection of (7?)-186b to Krapcho decarboxylation conditions (NaCl/wet DMSO/160 °C) afforded ethyl (3/?)-3(3-indolyl) 3-phenylpropionate (R)-181 (R = H, Ri = Et, Ar = Ph) in 74% yield. The diminished stereocontrol observed with this substrate relative to ßsubstituted α,β-unsaturated ketoesters was presumably because the alkylidene malonate bidentate catalyst complex would place the reacting olefinic center on the ligand C2-axis, farther from the chiral center than the reacting carbonyl of the Cu(BOX)-oc-ketoester alkylidene bidendate complex.

N H 128 (R = H) 136 (R Sub.)

A r ^

10mol%eachof of 188 and CuCI04.6H20,* C02Et 1:3 acetone/Et20, -20 °C C02Et

c

(188)

^ —

184b

^

Y>^

(S)-186b (73-99%, 88-93% ee) (R=H, 5-Me, 4-OMe, 5-OMe) (Ar=H, 4-halo, 2-CI, 3- & 4-NO2) 'Addition of ROH additive could potentiate reactivity but not % ee

Chapter 6 Transformations of Carbocycles

651

Tang from 2002 to 2004 published many papers76a'b demonstrating efficient asymmetric addition of unsubstituted (128) and substituted indoles 136 and ß-aryl substituted alkylidene malonates 184b using a novel copper catalyst (10 mol %) prepared either from a pseudo (^-symmetric functionalized triazoline (TOX) ligand 188 (all S-stereocenters) or from several modified BOX ligands (not shown).76c'd The initial coupling reaction was conducted in 1:3 acetone/Et20 at -20 °C using a copper catalyst complex derived from 10 mol % of TOX ligand 188 and Cu(C104)2*6H20 in 1:3 acetone/Et20, to afford the corresponding (5)-adduct, (S)-186b, in high yield (73-99%) and enantioselectivity (88-93% ee).76a The effect of reaction temperature (-20 °C) proved critical for optimal enantioselectivity. In addition, the reaction proved relatively insensitive to the electronics of indoles 128/136 (R = H, 5-Me and 4- and 5-OMe) and the Ar moiety of the ß-aryl alkylidene ethyl malonate 184b (Ar = 4-H, 4-halo, 2-C1, 3- and 4NO2). The TOX ligands of the catalyst were designed to be capable of a tridentate interaction with the metal center in the proposed catalytic cycle (see below). If V .

/^CH(C02R')2

ROhqCOzR'k 184b \

decomplexatibn R'O

complexation i2+

p-qu(Tox)(L)^ puiTOXXL),,1

addition H-transfer 128

\ N H

? -12+ .Cu(TOX)(L),l

The following results are not shown in the schemes but will be discussed. The reaction of unsubstituted indole 128 with benzylidene ethyl malonate 184b (where Ar = Ph) afforded a 50% yield and 85% ee of (S)186b (where Ar = Ph) at 0 °C, but with coaddition of 2 equiv (CF3)2CHOH, a clearly faster reaction with a higher yield (99%) and improved enantiocontrol (85% ee) was observed. The lower reaction temperature, however, appeared to be responsible for the improved stereocontrol. When the same reaction

652

Name Reactions for Carbocyclic Ring Formations

conditions using same additive was conducted at even lower temperature (25 °C), a modest compromise of conversion (84% yield) with improved stereocontrol (89% ee) of (5)-186b was realized. The enantioselectivity dropped considerably to 60% ee when the ß-aryl alkylidene substituent of (5)-186b was replaced with a β-ethyl alkylidene moiety (where Ar replaced by Et) and reacted with 128 the same reaction conditions. Thus this method proved limited to the use of benzylidene substituted malonates as substrates.76b A thorough investigation of the effect of solvent, variation in substrate stoichiometry, ratio of ligand/copper in complex, catalyst loading, reaction temperature, and chiral ligand was then undertaken. The optimal solvent system involved use of branched alcohol additive (2 equiv (CF3)2CHOH, 'PrOH, and 'BuOH), to speed up the reaction and the optimal trisoxazoline ligand containing 3(iS)-/5o-propyl substituents at the three isoxoazoline stereocenters. The addition of an alcohol as a coadditive (2 equiv) at low temperature (> -20 °C) was shown to accelerate both the reaction rate and enantioselectivity, which optimally led to its use as solvent. The use of bulkier branched alcohols as solvent gave an increase in stereoselectivity. The addition of > 200 equiv water apparently impaired catalytic activity but not enantioselectivity.76b These results suggest possible coordination of the alcohol moiety to the catalyst active site (possibly H2O from catalyst Οι(Οθ4)2·6Η2θ in initial scheme). The greater overall water tolerance and catalytic stability of the active intermediates of the trisoxazoline (TOX) catalyst complex over the (5)-Cu(OTf)2-'Bu bisoxazoline (BOX) catalyst system was initially attributed to the greater number of donor atoms involved. Deuterium labeling of the alcoholic solvent (ROD) showed 83% incorporation of the deuterium at the acidic cc-position of the malonate of 184b, showing the alcohol was involved in an H-transfer step (see catalytic cycle). The undeuterated product ($-186b remained unchanged when subjected to similar conditions and was consistent with the proposed catalytic cycle.76 Remarkable solvent effects were observed on the stereocontrol of this reaction. The use of either Cu(C104)2«6H20 and Cu(OTf)2 as sources of divalent copper ion were comparable in branched protic solvents, with the latter affording slightly better stereocontrol (~ 5% ee) at 15 °C. If the solvent was changed to a nonpolar aprotic solvent, a change to the opposite stereo orientation occurred [(S)-186b to (i?)-186b)]. This change was greatest whenl,l,2,2-tetrachloroethane (1,1,2,2,-DCE) was used as solvent. Treatment of a 10 mol % of ligand with 15 mol % Cu(OTfh in this solvent at 15 °C afforded the opposite enantiomer (/?)-186b in in 66% yield and 74% ee. Thus either enantiomer of adduct 186b could thus be obtained in reasonable enantiomeric purity just by change of solvent.76b'76e

Chapter 6 Transformations of Carbocycles

\

Ph

C0 2 Et

653

10mol%of 188 15mol%ofCu(OTf) 2 , Method A) TCE, 15 °C Method B) n-BuOH, 15 °C

C0 2 Et 128

184b

-Method A) (/^)-186b X=Ph, Y=H (66%, 74% ee) Method B) (Sj-186b X=H, Y=Ph (99%, 8 1 % ee)

The proposed stereoinduction model has the substrate/catalyst complex in a square pyramidal geometry with the slight excess of tritiate displacing a pendant isoxazoline, resulting in SZ-face attack and formation of (R)-lS6b. In fact, an X-ray structure previously reported by Evans of catalyst [Cu((5,,5)-'Bu-BOX)(H20)2](OTf)2, shows quite clear square-pyramidal geometry. Change to a catalyst coordinating solvent such as «-BuOH under the same reaction conditions, however, provided a 99% yield of (<S)-186b in 81% ee. The change in sense of stereoinduction in alcohol solvent assumes a distorted octahedral geometry with one of the sites occupied by the alcohol site with the Re-face exposed allowing selective formation of (5)-186b. A popular notion in asymmetric catalyses that an excess of a chiral ligand with respect to the metal improves enantioselectivity, because a background reaction by free metal is suppressed, proved not to be applicable in the next example. At the end of 2006, Reiser78 discovered that 5 mol % modified (5)-azabis(oxazoline) copper(II)-complex 189a (catalyst R = 'Pr with bis-ΟΎΐ counterion) or 189b (catalyst where R = Ph with ÒÙ-CIO4 counterion) could promote the addition of indole 128 to benzylidene malonates 184b to afford the (Ä)-enantiomer adduci, (7?)-186b, in 90-98% yield with up to > 99% ee, provided that excess of chiral ligand is avoided (see entries 1-5). The data suggest that one of the oxazole moieties of excess ligand could bind to the catalyst in the resting state (A). This would result in up to three nitrogen ligands being bound to copper in A. To reach the catalytically active species, one of the competing isoxazole ligands

654

Name Reactions for Carbocyclic Ring Formations 0-sX ' N\\

Ph^vA OEt

\

O^N)Et 184b

128 Entry 1) 2) 3) 4) 5) 6)

Catalyst Used 189a (X=NH) 189a (X=NH) 189a (X=NH) 189b (X=NH)* 189b (X=NH)* 92iii (X=CMe)2

PTV N

'Pf EtO

s Ligand Cu (II) O O

*Catalvst Changes CI04 Counterion instead of OTf and iPr replaced by Bn

\\

-Ns 'Pf

O

'Pf TfO

Solvent EtOH EtOH EtOH EtOH EtOH EtOH O-

IN-

Cu:Liqand (mol%i 1.0:1.30(3.8:5.0) 1.0:1.10(4.5:5.0) 1.0:1.04(4.8:5.0) 1.0:1.30(3.8:5.0) 1.0:1.04(4.8:5.0) 1.0:1.04(4.8:5.0)

II

98%(81%ee) 93% (85% ee) 97% (>99% ee) 90% (87% ee) 96% (95% ee) 89% (99% ee)

Q /*·.

/ C\ 'Pr TfO Ligand

'Pr EtO

OEt

Ph B-Low Enantioselectivity

Yield-186b (%ee)

Catalyst Resting State A-Catalyst/Ligand

\\

I

o7

x

Nv N Cu (II) 'Pr I

o

I

OEt

Ph C-High Enantioselectivity

has to dissociate off first to bind the two carbonyl moieties of the substrate. If subsequent dissociation of one of the chelating oxazoline moieties occurs to create a species such as B. The likelihood of this type of displacement would be higher in the presence of a higher than 1:1 stoichiometry of ligand-catalyst complex. The use of a ratio closer to 1:1 would have a greater likelihood of retaining the chelated bisoxazoline moiety coordinated to the copper and result in higher enantioselectivity (active complex C). All of these complexes may exist in overall square pyramidal geometry with the fifth position occupied by a tritiate or alcohol ligand (omitted for clarity).78a The most significant aspect of this work was that variation of the ligand: catalyst ratio should be investigated in cases where low enantioselectivity is observed. For example, use of (5)-Cu(OTf)2-'Bu-BOX catalyst 92iii in the same coupling reaction under the optimized reaction conditions (4.8/5.0 mol %, 1.0:1.04 Cu/ligand ratio) gave an impressive 89% yield of (R)-lS6b in 99% ee (entry 6). Increase of ligandxatalyst ratio to 1.0 : 1.20 under similar reaction conditions lowered the enantioselectivity of this conversion to 79% ee (results not shown in scheme). Thus the lower enantioselectivity (60% ee) reported for the same transformation by Jorgensen in 2001 using 92i (R = 'Bu) as catalyst may have resulted from differences in reaction conditions employed and not due to a greater

Chapter 6 Transformations of Carbocycles

655

proximity of the chiral ligand complex to the reacting olefinic center as had been originally speculated.783 Other significant articles from 2003 to 2005 not appearing in this chapter important to the development of the field include (1) Umani-Ronchi advances of the asymmetric F-C Michael-type reaction on the use of α,βunsaturated thioesters with a chiral Pd(II)-(Tol-binap) catalyst with the design of a single-point binding catalyst for this important transformation793-0 and (2) Ricci's use of chiral Jacobsen-type catalysts containing key requisite thiourea and hydroxyl moiety binding elements capable of bifunctional activation in the asymmetric F-C addition of nitroalkenes to unsubstituted indoles (128) (containing a few N-\ moiety) in preparation of chiral ß-alkyl and aryl functionalized tryptamine precursors.79

(110a or 192)/190/92i) 191a-g (82-95%, 68-97% ee) ,(2:1:0.1 Ratio in PCM) 20 °C,' 0 °C", 25 °C'" R2 R

1 ,,Ο

OH H' R3 193a-g (32-96%, 83-97% ee)

191 a)' b)' c)'" d)' e)" f)'" g)'"

R-I %Yieldi%eei Et 88%(94%ee) 'Bu 86%(94%ee) 2-ethyl(Ph)86%(92%ee) n-hexyl 82%(96%ee) 'Pr 86%(95%ee) cyclohexyl 84% (97% ee) Ph 95%(68%ee)

( °^Υ

V to.f Bu

s / -Cu.

0

>

O'('DVOH

. 'to,, Bu

Ar-HiSi)- Bottom

193 a)' b)' c)' d)' e)" f)' h)'

R, 2-ethyl(Ph) 2-ethyl(Ph) 2-ethyl(Ph) n-hexyl iPr cyclohexyl 4-CI(Ph)

R? H H MeO H H H H

R, %Yield(%ee) H 85% (94% ee) Me 89%,(93% ee) H 96% (97% ee) H 85% (96% ee) H 44% (85% ee) H 32% (85% ee) H 95%(83%ee)

Palomo in 2005 demonstrated that N-methyl pyrrole 110a in the presence of 10 mol % of (5)-Cu(OTf)2-'Bu-BOX catalyst 92i in DCM reacted with ß-alkyl- or aryl-substituted oc-hydroxyenones 190 to afford the corresponding optically active Friedel-Crafts pyrrole adducts (191a-g) in high yields (82-95%) and excellent enantioselectivities (68-97% ee). All enones of type 190 containing sterically hindered 2° alkyl R] substituents required higher temperatures (25 °C) for conversion than the corresponding 1° alkyl Rj moieties (-20 °C to 0 °C). The lowest enantioselectivity (68% ee) was obtained for a ß-substituted aromatic hydroxyenone (Ri = Ph, 191g).

Name Reactions for Carbocyclic Ring Formations

656

Indoles of type 192 also coupled well with 190, affording the corresponding adducts (193a-g in 32-96% yield and 83-97% ee. The authors also demonstrated that it was possible to transform the Friedel-Crafts alkylation products 191a-g and 193a-g into the corresponding optically enriched aldehydes, carboxylic acids, and ketones via standard elaboration of the ochydroxycarbonyl moiety (transformation steps not provided in the scheme).80 Evans, in a series of papers dated from 2003 to 2007, has reported the use of cationic Sc(III)-bis(oxazolino)pyridine catalysts (Scandium pybox) for the asymmetric Michael addition of electron-rich arenes to α,β-unsaturated 2-acylphosphonates and 2-acylimidazoles to afford the corresponding Michael adducts.8 la_e These catalysts are one of the most versatile in terms of matching high enantioselectivity and yield in substrate compatibility. The usefulness of this reaction is further enhanced by the synthetic flexibility in the conversion of these "active ester" adducts to new scaffolds. For example, the corresponding 2-acylphosphonate moiety of these adducts can be elaborated to the corresponding chiral ß-substituted acid, ester, and amide via a high yield nucleophilic displacement reaction. Adducts containing the more robust 2-acylimidazole moiety, however, offer even greater synthetic flexibility in that they can be converted to the corresponding chiral ßsubstituted aldehyde, ketone, acid, ester, and amide moieties using a one-pot two or three reaction sequence (ester/amide transformations shown).

u

OMe M e

2

N ^ ^

"<^y

"

194

195

N I

-ScTf0 OT >OTf 196

O

1)8mol%196,

i""0Me OMe

DCM,-78°C 2) MeOH/DBU

\ . ^ I ,p

1)10mol%196,

Me

2

N 198

i'OUe

195

OMe

DCM

) Morpholine

199(75%, 97% ee,-78 °C)

199 (99%, 96% ee, -56 °C)

Evans started with α,β-unsaturated 2-acylphosphonate 195 with ßmethyl substitution. Treatment of 3-A^JV-dimethylaminoanisole (194) with α,β-unsaturated 2-acylphosphonate 195 in the presence of 8 mol % of (S,S)-

Chapter 6 Transformations of Carbocycles

657

Sc(III)-Inda-pybox inflate complex 196 in DCM at -78 °C, followed by methanolysis of the resulting acylphosphonate Michael adduct using MeOH/DBU, gave the corresponding 3(S)-methyl substituted ß-aryl propionate methyl ester 197 in 76% yield and 87% ee. The reaction of 1methylindole (198, 0.2 M) with α,β-unsaturated 2-acylphosphonate 195 in the presence of 10 mol % catalyst 196 in DCM at -78 °C, followed by amination of the resulting acylphosphonate Michael adduct using morpholine, gave the corresponding morpholine 3(5)-methyl substituted ßaryl propionamide 199 in 75-78% yield and 96-97% ee (0.2M). At -56 °C, the yield of 199 was improved to 99% a identical enantiocontrol (96%).81a'd Variation of the 1-, 2- and 5-positions of the indole and ß-substituent of the α,β-unsaturated 2-acylphosphonate under identical reaction conditions (-78 °C, DCM, 10 mol% 196) are not shown in the scheme but will be discussed. Replacement of the N-Ì -methyl moiety of indole 198 with Nbenzyl, Ν-sdlyì and N-Me gave almost identical results in terms of yield of reaction (76-85%) and enantioselectivity (96-99%), but replacement of the indole ./V-1-alkyl moiety with H significantly lowered the enantioselectivity (83% ee) but not yield (83%). Replacement of the hydrogen at the 2-position of 198 with a 2-Me moiety led to a dramatic decrease in enantiocontrol (86%) but not yield (94%). It should also be noted that for ΛΜ-Βη indoles, the 5-position tolerated both electron-withdrawing and donating groups (C0 2 Me, halogen and OMe) relative to the parent N-l-Bn-5-i/-indole with yields (65-85%) and enatioselectivities ranging from 97-99% ee. Increase of the size of the ß-methyl (alkyl) asubstituent of 195 led to comparable yields and enantioselectivity (57% yield; 94% ee vs. 82% yield; 99% ee), where this substituent was replaced by CH2OTBDPS and 'Pr, respectively. A 3-phenyl (3-aryl) analogue, however, was not well tolerated (85% yield, 80% ee).81a'd

Several drawbacks in the use of the α,β-unsaturated 2acylphosphonates in acylphosphonates in the asymmetric Michael alkylation,

658

Name Reactions for Carbocyclic Ring Formations

including low substrate tolerance (only ß-alkyl substituted enones gave ee's > 90%) and, that for high levels of stereoselectivity (> 90% ee), the reaction had to be conducted at temperatures below -50 °C. In addition, the α,βunsaturated 2-acylphosphonates proved quite labile and could be prepared only in modest yields (20-47%). The pentagonal bipyramid geometry observed in the X-ray structure of this catalyst (196) led to the rationale that the sense of asymmetric induction is driven by placement of the sterically demanding phosphonate in the less demanding apical position orientating the oxygen toward the ligand plane. Thus addition of nucleophiles is believed to be directed from the indicated S-cis enoate diastereoface favored to minimize non-bonded interactions. Evans et al. then investigated use of more robust and easily prepared Michael acceptor substrates, such as TV-methyl (R = Me) α,β-unsaturated 2acylimidazole derivative 200a containing a small ß-methyl (Ri = Me) substituent.81b_d The asymmetric coupling of this substrate allowed great variation in the nature and size of both the R and the Ri substituent and flexible in the coupling of a wide range of arenes and related heterocycles. In addition, these reactions show great potential for pilot plant scale reactions that could be conducted at temperatures as high as 0 °C with < 2 mol % of the catalyst with very good enantiocontrol. For example, treatment of 2methoxyfuran 123 and N-U pyrrole 110b with 200a in the presence of 2 mol% of catalyst 196 in CH3CN 4 Ä MS at 0 °C afforded the respective 3(R)methyl substituted 1,4-adducts 201a (99% yield, 88% ee) and 202a (82%, 88% ee) in very good yield and enantioselectivity, respectively. The coupling of furan 123 and pyrrole 110b with 201b having a larger N-i-Vr substituent (R = 'Pr) under the same reaction conditions gave similar yield and improved enantioselectivities of the corresponding adducts 201b (85% yield, 89% ee) and 202b (90%, 93% ee). Evans completed the synthesis of (+)-heliotridine 205b from 202b using a using a two-step triflate-activated intramolecular amide cyclization of the pyrrole iV-H moiety onto the activated acyl imidazoium ion of 202b in the presence of Hunigs base to afford 203b as the key step to afford 203b. Hydrogenation of the pyrrole moiety of 203b and LÌAIH4 reduction of the resulting bicyclic tertiary amide 204b gave 205b. Coupling of the even larger jV-Ph imidazole-substituted Michael acceptor (200c, R = Ph) with pyrrole 110b under the coupling conditions led to a higher yield (98%) of 202c but resulted in no significant improvement of enantioselectivity (94%). Reduction of the reaction temperature to -40 °C in the coupling of furan 123 with 200a gave a reduced yield (65%) of 201a with improved enantiocontrol (98% ee).81b No significant improvement in enantiocontrol of 202b was observed in the coupling of pyrrole 110b with either ./V-methyl or the sterically more encumbered N-i-Pr substituted α,βunsaturated 2-acylimidazole 200a and 200b, respectively, when conducted

Chapter 6 Transformations of Carbocycles

659

under similar conditions (5 mol % of catalyst 196 at -40 °C versus 2 mol % of 196 at (TC). 8 "^ o +

123

Ri

N

201a (R,Ri = Me; 99%, 88% ee, 0 °C) 20la (R.R., = Me; 65%, 98% ee, -40 °C) 201b (R=Me, R='Pr; 85%, 89%, 0 °C)

200b (R='Pr, R^Me) O

110b

R

2 mol% 196,'or 5 mol% 196'^ MeCN, 4A MS 0°C'or-40°C"

200a (R=Me, Ri=Me) 200b (R='Pr, R,=Me) 200c (R=Ph, R,=Me) 200d (R='Pr, R-,='Pr) 200e(R='Pr, R^COzEt) 200f (R='Pr, R 1 =4-C0 2 Me(Ph) 200g (R='Pr, R1=4-MeO(Ph)

U-~V 202b

o

MeCN, 4Ä MS

200a (R=Me, R,=Me)

H

MeO.

2mol%196

^

202 R R, a)' Me Me a)" Me Me Me b)' 'Pr b)" 'Pr Me Me c)' Ph d)' 'Pr 'Pr ey 'Pr C0 2 Et f)1 'Pr 4-COzMe(Ph) g)' 'Pr 4-OMe(Ph)

%Yield. (% ee) 82%, (88% ee) 69%, (87% ee) 90%, (93% ee) 91%, (94% ee) 99%, (94% ee) 90%, (91% ee) 99%, (84% ee) 99%, (96% ee) 98%, (92% ee)

1)1.1 eq. MeOTf MeCN, 4Ä MS

1)H 2 , 5%Rh/AI 2 0 3

2) Hunigs Base

2) LiAIH4 203b (99%)

— 2 0 4 b (X=0) (90:10 dr) — 2 0 5 b (X=H,H) (+)-Heliotridine

A subsequent detailed study of the reaction has revealed an inverse correlation of higher catalyst loading with lower enantioselectivity, which may have offset any increase in stereoselectivity by lowering of the reaction temperature. In addition, Evans has also discovered that the temperaturedependent control of enantioselectivity of α,β-unsaturated 2-acylimidazole of type 200 was remarkably flat relative to the 2-acylphosphonate analogue 195.81d Investigation of pyrrole 110b, various ß-substituted (Ri-substituted) ./V-'Pr-substituted α,β-unsaturated 2-acylimidazole 200d-g (R = 'Pr), afforded the corresponding adducts 202d-g with a remarkable consistency of yield (90-99%) and enantioselectivity (84-96% ee). This is remarkable considering that the coupling of α,β-unsaturated 2-acylphosphonate 195

660

Name Reactions for Carbocyclic Ring Formations

worked well only with ß-alkyl substitution and required remarkably reduced temperatures (< -40 °C) to obtain good enantiocontrol. The following observations are not shown in the scheme but will be discussed. Replacement of the iV-H pyrrole 110b with the TV-methyl pyrrole 110a in the coupling of 200b (R = 'Pr) led to a significant loss of enantiocontrol (69% yield, 77% ee, 5 mol % of catalyst 196) even at low temperature (^10 °C). 2 mol% 196

>

MeCN, 4Ä MS -40 °C

2.5mol%196, 0 °C 1 mol%196,-40°C"/60°C 5mol%196,0°C' v /-40 o C MeCN, 4Ä MS 208

200a (R-, = Me) 200h (R, = 'Pr) 200i (R-i = Ph)

209 (43-99%, 65-98% ee)

Intramolecular cyclization of tethered indole 206 under the same catalytic conditions (2 mol % of 196) at -40 °C, gave an impressive 99% yield of 207 in 97% ee. To enantioselectively couple ^-substituted α,βunsaturated 2-acylimidazole of type 200 intermolecularly with indoles of type 208 under the standard coupling conditions (2.5 mol % 196 at 0 °C), capping of the free indole NH (R2 = H) was required (compare adducts 209A versus 209B obtained 65 and 93% ee, respectively, formed in the reaction of 200a (Ri = Me) with indole of type 208). Use of even less of the catalyst (1 mol % 196), at lower temperature (-40 °C) gave an improved 97% yield and 98% ee of 209B. Increase of the reaction temperature to 65 °C (minimum of 1 mol % of catalyst 196) afforded 209C in a surprisingly high 99% yield and 90% ee, highlighting the relatively flat temperature dependance of stereocontrol in the reaction.810 Substitution of the indole at C-2 with Me with a larger Ph moiety led to a significant drop in yield and stereoselectivity of 200 (88%, 91% ee) and 209E 43%, 66% ee). Alkylation of N-Bn indole (208) with 200a under the reaction conditions afforded 209F in 90% yield and 98% ee. There was no loss of stereocontrol of the reaction with replacement of the 5-H substituent of 208 with 5-halo or alkoxy substituent in the coupling of 200a to afford 209G in 70% (95% ee) and 209H in 99% yield (97% ee), respectively. Variation of the Ri ß-substituent of 200 from methyl (200a) to 'Pr (200g) or Ph (200j) in the coupling of iV-Me indole (208) showed no significant

661

Chapter 6 Transformations of Carbocycles

decrease of stereocontrol (compare 209b formed in 93% ee versus 209i and 209j formed in 94% and 91% ee, respectively). Overall, this coupling substrate showed the greatest flexibility in the coupling of arene heterocycles with a wide variety of ß-substituted (Risubstituted) 7V-'Pr-substituted α,β-unsaturated 2-acylimidazoles. The resulting acyl imidazolides could be converted in straightforward fashion to either aldehyde, ketone, acid, ester, or amide moieties using a one-pot two- or three-reaction sequence (not shown in scheme).81b_e The proposed stereoinduction model is complex and can vary, depending of the catalyst and active ester substrate used. The binding of the 2-acylimidazole substrate of type 200a to catalyst 196 is believed to lead to lead to a seven-coordinate pentagonal bipyramid 1:1:1 product/substrate/ catalyst complex at lower catalyst loading, but at higher catalyst loading, a pentagonal bipyramid 1:1 product substrate complex is believed to form. Both binding modes lead to the same stereochemical outcome in this case. The imidazole group is planar, and two of these units can occupy the equatorial positions of the catalyst, with one being the substrate and the other being the product molecule. This would place the carbonyl groups at the apical positions with the enone of the substrate oriented for nucleophilic attack on the i?e-face, in accord with a sense of stereoinduction observed in the reaction according to Evans.81d' In 2009, the general asymmetric coupling of substituted pyrroles (110) and indoles (208) with 2-acylimidazole substrate of type 200 was extended to other catalyst complexes such as 0.15-0.3 mol % of copper 4,4'dimethyl-2,2'-bipyridine [Cu(dmbpy)]/DNA complexes [1.4-7 ug/mL DNA base pairs] in aqueous media. Good enantioselectivities (83-93%) of the corresponding adducts 202 and 209, respectively, were observed using sources of DNA such as st-DNA (salmon testes-DNA) and DNA-1 with the self-complimentary sequence of d(TCAGGGCCCTGA)2. A key limitation of this approach was the requirement of at least 5:1 ratio of arene to 200 to achieve good conversion to the adducts (no scheme provided)

Xx

n

Brr

'

N

Xti Q*«-

n

Ph

Ph

N n N H.HX H 211A(Y='Bu) 212 (No HX Needed) 211B(Y=5-Me-2-furyl) (For catalysts 210-211A, 211B, HX usually TFA or HCI salt)

Dn

H.HX 210

Brr

'

c n

Name Reactions for Carbocyclic Ring Formations

662

The final portion of section E will focus on the use of covalent binding secondary amine organocatalysts such 210-212 for the asymmetric F-C Michael Type alkylations of arenes with α,β-unsaturated aldehydes of type 213, first pioneered by MacMillan back in 2000.82a_<1 The initial organocatalysts used (i.e., 210, 211A) were prepared in just a few synthetic steps on pilot plant scale from inexpensive commercially available amino acids (not shown in scheme). Catalyst loading for these type of covalent organocatalysts is typically much higher (~ 20 mol %) than for the aforementioned chiral thiourea and Bronsted acid organocatalysts (typically < 5 mol %), which involve noncovalent H-bonding interactions essential for catalyst activity. Thus the ease of preparation on scale is important to the practicality of the methodology. During the period 2000-2002, MacMillan's group reported the asymmetric coupling of substituted electron-rich arenes (anilines 214), pyrroles (216) and indoles (218) with α,β-unsaturated aldehydes (213) in the presence of 20 mol % organocatalyst 210 or 211A to afford the corresponding adducts (215, 217, and 219, respectively), in very good yields and enantioselectivities. 2a_c Thus secondary amine organocatalysts forming reversible chiral iminium ions in situ which increase reactivity of the electrophile by LUMO activation as well as provide a spatially discriminating environment for enantiofacial (Re-face selectivity of the alkene moiety) and regioselective 1,4-addition by the arene moiety. X O

Ri

RoN

214

10-20mol%211A, H

O +

216

R

H

Ri^^^H 213

R,N 2 1 5 (>1Q% 7 2 . 9 7 o / o e e ) V

'

20mol%210, THF/H2O/-30 to -60 °C

(Ri=alkyl, aryl, C02Me, CH2OBn) (R3=Me, Bn, allyl) 217 (>73%, 86-99% ee) O

R4

218

^

213

ΓΎΛ.N

DCM or CHCI3 -20 °C to RT

(R=alkyl andX=OMe, H, CI, SMe) (R-,=alkyl, aryl, C02Me, CH2OBn)

213

HR o

20mol%211A, DCM/IPA/-50 to-90 °C

(R-,=alkyl, aryl, C02Me, CH2OBn) 219 (>72%, 89-97% ee) (R4=H, alkyI) (R5=Me, CI, OMe)

Chapter 6 Transformations of Carbocycles

663

Overall, 211A is a better better designed catalyst than 210 though both may be adequate if the arene and Michael acceptor 213 are of appropriate reactivity. The only difference in the catalysts is that the geminai dimethyl position of the aminal moiety of 210 is replaced by the ß-chiral (Bu moiety (211 A). Several control elements are at work. The lone pair of the secondary amino moiety of catalyst 210 required for formation of the iminium ion is sterically less accessible (vicinal geminai dimethyl groups occupies space on both faces) and is less reactive than with catalyst 211A where a hydrogen is syn to the lone pair and the 'Bu moiety occupies the opposite face. The catalyst-activated iminium ion complex of 211A:213 was anticipated to more optimally populate the (£)-isomer to avoid nonbonding interactions between the substrate olefin and the 'Bu moiety. As a result, the benzyl group on the catalyst framework will effectively shield the 57-face of the activated olefin, leaving the Re-face exposed to indole addition, leading to the (Ä)-adducts with high stereoselectivity. The same steric influences of the iminium ion complex of both catalysts preclude arene 1,2-addition.

Recently, Wang (2009) demonstrated a practical improvement of this methodology through the use of Lewis base-Lewis base bifunctional catalysis instead of the traditional MacMillan base catalyst with acid cocatalysts of formula HX.82e It was shown that coupling of a wide variety of N-i unsubstituted Rs-substituted indoles of type 218 (R4 = H, 1.20 equiv) and ß-substituted α,β-unsaturated aldehydes (213, 1.0 equiv) in the presence of diphenyl prolinol TMS ether catalyst 212 (5-20 mol %) in ethereal solvents such as TBME at 25 °C to -20 °C could afford adducts 219 in very good yields (66-95%) and enantioselectivities (92-98%).

Name Reactions for Carbocyclic Ring Formations

664

> +R ^ J

N R4

218 (1.2 eq.)

R

1 ^

H

H

20mol%212

·■

50mol%Et 3 N 0 to -20 °C, MTBE

213 (1 eq.) (R1 = alkyl, aryl, and R4 = H) 219 (R5=2-Me, 5-OMe, 5-Br, 7-Me) (66-95%, 92-98% ee)

In this mode of catalysis, it is believed that chiral amine Lewis base catalyst 212 was used to activate the α,β-unsaturated aldehyde 213 by lowering the energy of the LUMO of the electrophile and induction of chirality of the reaction through covalent formation of the intermediate iminium ion complex as proposed by MacMillan.82a_c The difference with this bifunctional catalysis mechanism is that addition of a second Lewis base (i.e., triethylamine) acts as a cocatalyst to activate the nucleophilic reagent (indole N-H moiety) by raising the energy of the HOMO of the nucleophile by deprotonation or hydrogen-bond interaction (lowering the resulting LUMO-HOMO gap),m increasing the efficiency and practicality of the process. The elimination of the potentially corrosive acid cocatalyst and use of higher reaction temperature make this method attractive for optimization on pilot plant scale. This method does have the limitation that the nucleophile 218 (./V-H indoles, where R4 = H) must be capable of activation by the base cocatlyst (Et3N or 'Pr2NEt).82e The following results are not shown in the scheme but will be discussed. The reaction proved equally effective in other ether based solvents such as THF, ether, dioxane, and DME but gave no conversion to the product in polar aprotic solvents such as DMF or CH3CN. It is interesting that use nonpolar solvents such as toluene and DCM gave adequate conversion very poor stereocontrol (< 40% ee) in formation of the adduct. It was also demonstrated that as little as 5 mol % of catalyst 212 could be used, though a detailed study of the effect of lowering the catalyst loading wasn't reported.826

Chapter 6 Transformations of Carbocycles

665 Bn

1, >=o

H

220

20mol%211A,i DCM -40 °C, 24h

Intermediate 221

213

Several Steps

223 (-)-Flustramine B

BOC

222 (78%, 90% ee)

Several medicinally important active agents were reported to be synthesized using the MacMillan coupling methodology as the key step in the syntheses. In 2004, MacMillan completed an elegant synthesis of (-)Flustramine, a pyrrolidinone marine alkaloid (K-channel blocker) using a cascade-cyclization strategy,82f whereas workers at Bristol-Myers Squibb in 2005 synthesized a serotonin reuptake inhibitor (SRI) for potential use as an antidepressant via the use of a modified MacMillan catalyst 211B.82g Impressive examples of highly enantioselective intramolecular indole cyclizations were reported by Xiao in 2007 (scheme and results not shown). One limitation of this method was that it can be applied only enantioselectively to less reactive or,y#-unsaturated aldehydes and not the corresponding ketones. Many successful strategies for the asymmetric Friedel-Crafts alkylation of indoles with or,/?-unsaturated enones catalyzed by Lewis acids79b'c'84a'b or organocatalysts853-6 have also recently been reported. Two of these methods published in 2007 involve use of noncovalent organocatalysts using H-bonding interactions by creation of a catalytic salt by combination of an achiral85b and chiral Bronsted acid85c with a Brensted base derived from a primary amine modified cinchona alkaloids. They were applied to afford the corresponding indole adducts with stereocontrol up to 88-96% ee, respectively.

Name Reactions for Carbocyclic Ring Formations

666

6.2.8

Experimental

CI

ci

11 13

14

AICI3 Et3SiH or PMSH/DCM (85%)

15(X = 0) 16(X=H,H)

One-Pot two-step generalized procedure for the preparation of l-(4chlorobutyi)-4-methylbenzene (16) from 4-chlorobutanoyl chloride (14) and toluene (13) A solution of 5.12g (36.3 mmol) 4-chlorobutanoyl chloride (14) was stirred in 30 mL CH2CI2 and 4.4 g (33.0 mmol) anhydrous AICI3 was slowly added. The reaction mixture was stirred until reaction completion. To this mixture at 25 °C was added a solurtion of 2.76 g (30.0 mmol) toluene in 10 mL of CH2C12, followed by addition of neat 9.25 g, (80 mmol) neat Et3SiH (80.0 mmol). The reaction mixture was stirred until reaction completion then subjected to traditional aqueous workup with purification by chromatography to afford 3.81 g (86%) 16: b.p. 97-100 °C/0.015 mm Hg). MeO

' γ ^ 0^0^|_ MeO'Χ^Κ^^γΟ 23

11

u

Cataìy'st°

CH 3 N0 2 100 °c

M e

°V^rA_ Me(yK^~

24 (Catalyst. Yields BF3.OEt2 90% Sc(OTf) 3 85% TfOH 86%

General preparation of 5,6-dimethoxy-2-methyl-2,3-dihydro-l//-inden1-one (24) from 23 33f h To a flame-dried two-necked flask equipped with reflux condensor preheated to 100 °C was added 5 mL of a 0.095 M CH3NO2 solution of Meldrum's acid derivative 23 (0.475 mmol) under a dry N2 atmosphere. The solution was heated 5 min; after which, 10 mol% (0.0475 mmol) of the catalysts (9 μ ί BF3-OEt2, 5 μ ί TfOH or 25 mg Sc(OTf)2) wer e quickly added. The solution was heated to reflux for 20 min. The mixture was cooled to rrom temperature and concentrated, and the residue was purified by silica gel flash chromatography, eluting with 2:1 ethyl acetate/hexane to afford 24 as a white solid (m.p. 131-132 °C) in the yields indicated in the table.

Chapter 6 Transformations of Carbocycles OMs

667

Ph

phH

AICI3 (3.6 eq.) Temp 10 °C

N/

Bz

"C02H

46 75%, >99%ee

Preparation of frans-l-Benzoyl-4-Phenyl-L-Proline (46) from 44 39b To a dry t,hree-necked, 2-L Morton flask equipped with overhead stirrer, temperature probe and N2 inlet was added 124.2 g (3.6 equiv, 0.93 mol) AICI3 in 810 mL benzene. The mixture was cooled as necessary in a dry ice/acetone bath with the slow addition of 81.0 g (0.26 mol) 44 in small solid portions at a rate to maintain the internal temperature at 6 °C (removal of bath as necessary). The mixture was stirred 5.5 h, allowing the internal temperature to rise from 7 to 10 °C as necessary by cooling. The resulting homogeneous mixture was hydrolyzed by the slow addition of 990 mL (2.97 mol) 3 M aqueous HCl solution so the internal temperature did not exceed 30 °C. The solution was diluted with 180 mL brine and stirred at room temperature overnight, the resulting precipitated crude product containing 46 was filtered. The resulting solid was washed with 390 mL (0.39 mol) 1 N HCl and water (4 χ 500 mL). The resulting crude product was dissolved in 240 mL hot «-butyl acetate, dried (anhydrous Na2SC>4), cooled to room temperature and seeded to promote recrystallization. A total of 57.4 g (75%) enantiomerically pure 46 was isolated after suitable drying as a white solid [m.p. 137-138.5 °C), [a] D -62.3 (MeOH, c = 1)].

\ N

H

104

9 F3C

5 mol% 102, Et 2 0, -8 °C C0 2 Et

96

Where Ri=5-OMe 105 via cinchonidine-102

(98%, 93% ee)

Preparation of (S)-3,3,3-trifluoro-2-hydroxy-2-(5-methyl-3-indolyi)propionic acid ethyl ester (105, Ri = Me) from 102 (Ri = Me), and 96 via cinchonidine alkaloid catalyst 10256b To a sealable glass reaction vessel under inert atmosphere containing 5methylindole (0.5 mmol) and cinchonidine (102, 0.0375 mmol) was added 3 mL anhydrous Et20. The solution was stirred at - 8 °C (salt-ice cooling bath) for 30 min. Then 0.75 mmol ethyl 3,3,3-trifluoropyruvate was added, and the mixture was stirred at - 8 °C (salt-ice cooling bath) for 3 h. The mixture was concentrated with removal of the solvent and excess ethyl trifluoropyruvate

Name Reactions for Carbocyclic Ring Formations

668

by evaporation. The mixture then was dissolved in ether and the catalyst was removed by use of 500 mg scavenging agent K-10 montmorillonite (a solid acid). The cinchonidine-K-10 complex was removed by filtration and the solvent evaporated to afford 105 (Ri = Me) in 98% yield and 93% ee (chiral HPLC): mp 75.2-76.5 °C Ph NHAc

OH N H 136(R = 4-OH)

10 mol% (S)-125 4Ä MS, PhMe, 25 °C » AcHN^^ Ph (143, Ar = Ph)

144 95% (86% ee)

Preparation of (5)-AL(l-(4-hydroxy-l//-indol-3-yl)-l-phenylethyl)acetamide (144, Ar = Ph, R = 4-OH) from 4-hydroxyindole (136, R = 4-OH), enamide (143, Ar = Ph) and chiral phosphoric acid catalyst (125)63b To an oven-dried Schlenk tube was added phosphoric acid (S)-125 (7.5 mg, 0.01 mmol), 4-hydroxyindole 136 (0.14 mmol), N-(l-phenylvinyl)acetamide (enamide 143, Ar = Ph, 0.1 mmol), and 90 mg 4 À molecular sieves. The mixture was degassed, placed under a N2 atmosphere dissolved in toluene (1.5 mL) and stirred at RT until TLC indicated reaction completion. The solvent was removed under vacuum and the residue purified by flash column chromatography on silica gel (eluted with 1:1 ethyl acetate/petroleum ether to afford the (S)-adduct 144 (R = 4-OH) in 95% yield and 86% ee: m.p. 107110 °C; [a]D = -62.3 (c 0.7, acetone).

\ N H (1 equiv) 128

Method A (R=H, Me, OMe) 5 mol% 160 TMSCI (2 eq.) H20 (8 mol%)

AcO (1 equiv) 159i(n=1)

» TBME(0.12M), -30 °C 161a (n = 1) 90, (93% ee)* *99% ee (Et20)

Preparation of (i?)-l-benzyl-5-(l//-indol-3-yl)pyrrolidin-2-one (161a) from Indole (128), l-benzyl-5-oxopyrrolidin-2-yl acetate (159i, n = 1): and thiourea catalyst (160) using method A68

Chapter 6 Transformations of Carbocycles

669

The thiourea catalyst 160 (0.110 g, 0.156 mmol) and indole (0.367 g, 3.15 mmol, 128) were each placed in a 100-mL flame-dried round-bottomed flask, which was sealed with a rubber septum. The flask was flushed with N2, and anhydrous TBME (14.7 mL) was added. The resulting yellow solution was cooled to -78 °C, and a solution of acetoxylactam 159i in TBME (6.0 mL, 6.34 mmol, 0.53 M) was added. Next, solutions in TBME of TMSC1 (3.95 mL, 6.34 mmol, 1.6 M) and H 2 0 (1.84 mL, 0.276 mmol, 0.15 M) were added sequentially, and the mixture was warmed to -30 °C and stirred for 24 h. The heterogeneous reaction mixture was quenched by the addition of a solution of NaOEt in EtOH (1.84 mL, 21 wt %), followed by the immediate addition of water (9.2 mL). The mixture was allowed to warm to room temperature and was diluted with EtOAc until all solids had dissolved (the amount of EtOAc added (90 mL). The layers were separated, and the organic layer was dried (Na2SÜ4) and concentrated in vacuo. The crude product (93% ee) was purified by trituration from EteO ( 3 x 1 0 mL) to yield 161a (0.854 g, 90% yield, 99% ee) as a colorless crystalline solid: [a]D = ^19° (c = 1.3, MeOH).

206

207 (99%, 97% ee)

-^NV^

Preparation of (Ä)-l-(l-methyl-l^-imidazol-2-yl)-2-(2,3,4,9-tetrahydrol#-carbazol-l-yl)ethanone (207) from (E)-6-(l//-mdol-3-yl)-l-(l-methyll#-imidazol-2-yl)hex-2-en-l-one (206) and catalyst complex (196) 81bd To a dried 2-dram vial in a drybox was added an appropriate amount scandium(III) triflate, 4 Ä MS (15 mg/0.13 mmol of substrate), and 1.2 equiv (5)-Indapybox ligand. The vial was capped with a septum and purged with 1 mL dichloromethane. The catalyst was allowed to age for 2 h at rt. The dichloromethane was removed by a steady stream of N2 to afford catalyst complex 196. To 2 mol % (0.0021 mmol) 196 was added 1 mL of acetonitrile. The reaction was cooled to -40 °C for 15 min before 30 mg (0.103 mmol, 1 equiv) (£)-6-(l//-indol-3-yl)-l-(l-methyl-l^-imidazol-2yl)hex-2-en-l-one 206 was added to the vial. After 18 h of moderate stirring at -40 °C, the title compound was purified by flash silica chromatography (Rf = 0.31, 50% EtOAc/hexanes) to afford 30 mg (99% yield, 97% ee) 207.

670

Name Reactions for Carbocyclic Ring Formations

220

213

222 (78%, 90% ee)

Preparation of (S)-6-bromo-8-(3-prenyi)-3a-(3-oxo-propyi)-3,3a,8,8atetrahydro-2//-pyrrolo[2,3-é]indole-l-carboxylic acid tert-butyl ester (222) from W-lO-BOC-l-prenyl-ó-bromotryptamine (220), acrolein (213), and MacMillan catalyst 21 lA82f To an amber 2-dram vial equipped with a magnetic stir bar was added (25,,55)-5-benzyl-2-fór/-butyl-3-methyl-imidazolidin-4-one (catalyst 211 A) in 4.2 mL CH2C12 cooled to -84°C, 258 mg acid (9.8 pL, 0.13 mmol) was added, followed by trifluoroacetic acid (0.64 mmol) and iV-10-BOC-lprenyl-6-bromotryptamine (220). The solution was stirred for 5 min before addition of 0.17 mL (2.56 mmol) acrolein 213 and then stirred for 72 h. The resulting suspension was stirred at constant temperature until complete consumption of the indole was observed as determined by TLC. The reaction mixture was then treated with 20 mL pH 7.0 buffer and extracted with diethyl ether (2 χ 25 mL) and concentrated in vacuo. The resulting residue was purified by silica gel chromatography (solvents noted) to afford 222 as a colorless oil (231 mg, 78% yield, 90% ee) after silica gel chromatography in 10% EtOAc/hexanes as a colorless, viscous oil. [α]π = -218.9 (c = 1.0, CHC13). 6.2.9 References 1. 2. 3. 4. 5. 6. 7. 8. 9.

[R] Olah, G. A.; Krishnamurti, R.; Prakash, G. K. S. in Friedel-Crafts Alkylation in Comprehensive Organic Synthesis, Vol. 3, Trost B. ML, Fleming I. eds.; Pergamen Press, Oxford, 1991, 293. Miethchen R.; Kroger C.-F. Z. Chem. 1975,15, 135. [R] Olah G. A., Dear R. R. Friedel-Crafts and Related Reactions, Wiley-Interscience, New York, 1963-1965. [R] Roberts, R. M.; Khalaf, A. Friedel Crafts Alkylation Chemistry: A Century of Discovery, Marcel Dekker, New York, 1984. [R] Olah G. A. Friedel-Crafts Chemistry, Wiley-Interscience, New York, 1973. [R] Ashdown, A. Ind. Eng. Chem. 1927, 1063. Crafts, J. M.; Friedel C. Compt. Rend. 1877, 84, 1450. See also Crafts, J. M.; Friedel C. Compi. Rend. 1877, 85, 74 and 673. [R] Olah G. A.; Krishnamurphy, R.; Prakash, G. K. S. In Kirk-Ohmer Encyclopedia of Chemical Technology, 5th Ed 2005, 12, 159. For a detailed list of relative Lewis acid activities in F-C reactions, see Table 1, page 1071. [R] Price, C. C. In Organic Reactions, Wiley, New York, 1946, 3, 2.

Chapter 6 Transformations of Carbocycles 10. 11. 12. 13. 14. 15.

16. 17. 18. 19. 20.

21. 22. 23. 24. 25. 26. 27. 28. 29. 30.

31. 32. 33.

34. 35.

671

[R] Laue, T.; Plagens, A. Named Organic Reactions Wiley, New York, 2005, p. 120. Brown, H. C. J. Am. Chem. Soc. 1953, 75, 6285. Olah, G. A.; Kuhn, S. J. J. Am. Chem. Soc. 1958, 80, 6541. Effenberger, F. Chem. Unserer Zeit 1979,13, 879. [R] Smith, M. B.; March, J. March's Advanced Organic Chemistry Wiley, New York, 2001, p. 711. (a) Nakajima, T.; Suga, S.; Sugita, T.; Ichikawa, K. K. Tetrahedron 1969, 25, 1807. (b)See also Nakajima, T.; Nakamoto Y.; Suga, S. Bull. Chem. Soc. Jpn. 1975, 48, 960. (c) For cases of almost 100% inversion, see Piccolo, O.; Azzena, U.; Melloni, G.; Delogu, G.; Valoti, E.; J. Org. Chem. 1991,56, 183 Brown. H. C; Jungk, H. J. Am. Chem. Soc. 1956, 78, 2182. [R] Barton, D.; Ollis, W.D. "Comprehensive Organic Chemistry" Pergamon Press, New York, 1979, /, 268-269. Olah, G. A.; Olah, J. A. J. Am. Chem. Soc. 1976, 98, 1839. Tagematsu, A.; Sugita, K.; Nakane R. Bull. Chem. Soc. Jpn. 1978, 51, 2082. (a) Olah, G. A.; Kobayashi, S.; Tashiro, M. J. Am. Chem. Soc. 1972, 94, 7448. See also Asaoka T.; Shimasaki, C; Taki, K.; Funayama, M.; Sakano M.; Kamimura, Y. Yuki Gosei Kagaku Kyokai Shi, 1969, 27, 783. For earlier study, see Russell, G.; J. Am. Chem. Soc. 1959, 81, 4834, [R] (b) For an impressive review of Lewis acid in homogenerous and heterogeneous catalysis, see Corma, A.; Garcia, H. Chem. Rev. 2003, 103, 4307. Mine, N.; Fujiwara, Y.; Taniguchi, H. Chem. Lett. 1986, 357. Nenitzescu, C. D.; Cantuniari, E. 1. P. Chem. Ber. 1933, 66, 1097. Allen, R. H.; Yats, L. D. J. Am. Chem. Soc. 1961, 83, 2799. Jacobsen O. Chem. Ber. 1885,18, 338. Bun-Hoi, N. G.; Cagneunt, P. Bull. Soc. Chim. Fr. 1942, 9, 887. Ipatieff, V. N.; Pines, H.; Schmerling, L. J. Org. Chem. 1940, 5, 253. Tashiro, M. Synthesis, 1979, 921. (b) Tashiro, M.; Itoh, T.; Yoshiya, H.; Fukata, G. Org. Prep. Proc. Ml. 1984,16, 155. McOmie, J. F. W.; Saleh, S. A. Tetrahedron 1973, 29, 4003. Lewis, N.; Morgan, I. Synth. Commun. 1988, 18, 1783. [R] (a) See Francis, A. W.; Reid, E. E. Ind. Eng. Chem. 1946, 38, 1194. and Weisgermel, K.; Arpe, H. J. Industrial Organic Chemistry, Verlag Chemie, Berlin, 1978. (b) Green, M. M.; Witcoff, H. A. Organic Chemistry Principles and Industrial Practice Wiley-VCH, Weinheim. 2003. pp. 10-21, (c) [R] For an excellent review on the use of clays in synthesis including F-C Reactions, see Dasgupta, S.; Török, B. Org. Prep. Proc. Ml 2008, 40, 1. Calloway, N. O. J. Am. Chem. Soc. 1937, 59, 1474, Brown H. C; Junck, H. J. Am. Chem. Soc. 1955, 77, 5584. For selective monoalkylation of dihaloalkanes containing different halo groups, see Olah, G. A.; Kuhn, S. J. J. Org. Chem. 1964, 39, 2317. [R] Carey, F. A.; Sundberg R. J. Advanced Organic Chemistry. Part B: Reaction and Synthesis Plenum Press, New York, 1980, p. 267. (a) Eisenbraun, E. J.; Hinman, C. W.; Springer, J. M.; Burnham, J. W.; Chou, T. S.; Flanagan, P. W.; Hamming, M. C. J. Org. Chem. 1971, 36, 2480. [R] (b) For a review of the Haworth reaction sequence, see Agranaut, I.; Shih, Y. J. Chem. Educ. 1976, 53, 488. (c) Jaxa-Chamiec, A.; Shah, V. P.; Kruse, L. I. J. Chem. Soc. Perkin Trans. 11989, 1705. (d) Coppi, L.; Ricci, A.; Taddai, M. J. Org. Chem. 1988, 53, 911. (e) Aggarwala, V. P.; Gopal, R.; Garg, S. P. J. Org. Chem. 1973, 38, 1247. (f) Fillion, E.; Fishlock, D. Tetrahedron 2009, 65, 6682. (g) Fillion, E.; Fishlock, D. Wilsilly, A. Golf, J. M. J. Org. Chem. 2005, 70, 1316. (h) Fillion E.; Fishlock, D. Org. Lett. 2003, 5, 4653. (i) Li, W.; Lai, H.; Ge, Z.; Ding, C; Zhou, Y. Synth. Commun. 2007, 37, 1595. (a) Brown, H. C; Marino, G.; Stock, L. M.; J. Am. Chem. Soc. 1959, 81, 3310. (b) Brown, H. C; Marino, G. J. Am. Chem. Soc. 1959, 81, 5610. (c) Olah G. A.; Moffatt, M. E.; Kuhn, S. J.; Hardie, B. A. J. Am. Chem. Soc. 1964, 86, 2198. (a) Olah, G. A.; Kobayashi, S. J. Am. Chem. Soc. 1971, 93, 6964. (b) Teranishi, K.; Hayashi, S.; Nakatsuka, S.; Goto, T.; Synthesis 1995, 506. [R] (c) For an excellent review on green homogeneous and heterogeneous catalysis describing advances, including the modern uses of supercritical C0 2 and ionic liquids to improve reactivity in F-C reactions, see Como, A.; Garcia, H. Chem Rev. 2003,103,4307.

672 36. 37. 38. 39. 40. 41. 42. 43. 44. 45. 46. 47. 48. 49. 50.

51. 52. 53. 54. 55.

56.

57. 58. 59. 60.

61. 62. 63. 64.

Name Reactions for Carbocyclic Ring Formations Brauman, J. I.; Solladie-Cavallo, A. J. Chem. Soc, Chem. Commun. 1968, 1124. Brauman, J. I.; Pandell, A. J. J. Am. Chem. Soc. 1967, 89, 5421. Masuda, S.; Nakajima, T.; Suga, S. Bull. Chem. Soc. Jpn. 1983, 56, 1089. (a) Kronenthal, D. R.; Mueller, R. H.; Kuester, P. L.; Kissick, T. P.; Johnson, E. J. Tetrahedron Lett. 1990, 31, 1241. (b) For procedural details, see US Pat. 4,912,231. Scholkopf, U.; Grutter, S.; Anderskewitz, R.; Egert, E.; Dyrbusch, M. Angew Chem., Int. Ed. Engl. 1987,26, 683. Matsumoto, T.; Maeta, M.; Suzuki, K.; Tsuchihashi, G. Tetrahedron Lett. 1989, 30, 833. Kotsuki, H.; Hayashida, T.; Shimanouchi, T.; Nishizawa, H. J. Org. Chem. 1996, 61, 984. Bandini, M.; Cozzi, P. G.; Melchiorre, P.; Umani-Ranchi, A. J. Org. Chem. 2002, 67, 5386. Bandini, M.; Cozzi, P. G.; Melchiorre, P.; Umani-Ranchi, A. Angew. Chem., Int. Ed. 2004, 43, 84. [R] (a) Y.Wang, K. Ding, L. Dai, Chemtracts 2001,14, 610. [R] (b) Bandini,'M.; Cozzi, P. G.; Melchiorre, P.; Umani-Ranchi, A. Angew. Chem., Int. Ed. 2004, 43, 550 [R] Poulson, T. B.; Jorgensen, K. A. Chem. Rev.2008, 108(8), 2903. F. Bigi, G. Casiraghi, G. Casnati, G. Sartori, J. Org. Chem.1985, 50, 5018. G. Erker, A. A. H. van der Zeijden; Angew. Chem., Int. Ed. Engl. 1990, 29, 512. A. Ishii,V. A. Soloshonok, K. Mikami, J. Org. Chem. 2000, 65, 1597. See reference 13 of reference 46 cited within (vide supra) and for examples of homogeneous catalysis, see: (a) Yadav, J. S.; Subba Reddy, B. V.; Murthy, C. V. S. R.; Mahesh Kumar, G.; Madan, C. Synthesis 2001, 783. (b) Hao, J.; Taktak, S.; Aikawa, K.; Yusa, Y.; Hatano, M.; Mikami, K. Synlett 2001, 1443. (c) For examples of heterogeneous catalysis, see Ramesh, C; Banerjee, J.; Pal, R.; Das, B. Adv. Synth. Catal. 2003, 345, 557 . Dong, H.-M.; Lu, H.-H.; Lu, L.-Q.; Chen, C.-B.; Xiao, W.-J. Adv. Synth. Catal. 2007, 349, 1597. Gathergood, N.; Zhuang, W.; J0rgensen, K. A. J. Am. Chem.Soc. 2000,122, 12517. [R] (a) For a review of the use of chiral bisoxazoline-Lewis acid complexes in asymmetric synthesis, see Desimoni, G.; Faita, G.;Jorgensen, K. A. Chem. Rev. 2006, 106, 3561. [R] (b) Johnson, J. S.; Evans, D. A. Ace. Chem. Res. 2000, 33, 325.. Zhuang, W.; Gathergood, N.; Hazell, R. G.; Jorgensen, K. A. J. Org. Chem. 2001, 66, 1009. [R] For recent reviews on catalysis by chiral Bronsted acids in asymmetric F-C reactions, see (a) Connon, S. J. Angew. Chem., Int. Ed. 2006, 45, 3909. (b) Akiyama, T.; Itoh, J.; Fuchibe, K. Adv. Synth. Catal. 2006, 348, 999. (c) Taylor, M. S.; Jacobsen, E. N. Angew. Chem. 2006, 118, 1550. (d) Taylor, M. S.; Jacobsen, E. N. Angew. Chem., Int. Ed. 2006, 45, 1520. (a) Török, B.; Abid, M.; London, G.; Esquibel, J.; Török, M.; Mhadgut, S. C; Yan, P.; Prakesh, G. K. S. Angew. Chem., Int. Ed. 2005, 44, 3086. (b) Török, B.; Abid, M.; London, G.; Esquibel, J.; Török, M.; Mhadgut, S. C; Yan, P.; Prakesh, G. K. S. Angew. Chem. 2005, 777,3146. (a) Johannsen, M. Chem. Commun. 1999, 2233. b) Saaby, S.; Fang, X.; Gathergood, N.; Jorgensen, K. A. Angew. Chem. Int. Ed. 2000, 39,4114. (c) Saaby, S.; BayLn, P.; Aburel, P. S.; Jorgensen, K. A., J. Org. Chem. 2002, 67, 4352. Terada, M.; Sorimachi, K.; Uraguchi, D. J. Am. Chem. Soc. 2004,126, 11805. Jia, Y.-X.; Xie, J.-H.; Duan, H.-F.; Wang, L.-X.; Zhou, Q.-L. Org. Lett. 2006, 5, 1621. For a general review of chiral H-bond donars in asymmetric catalysis including Jacobsen type thiourea catalyzed reactions, see the following articles and references cited within [R] (a) Doyle, A. G.; Jacobsen, E. N. Chem. Rev. 2007,107, 5713-5743. (b) See also references cited within Taylor, M. S.; Tokunaga, N.; Jacobsen, E. N. Angew. Chem., Int. Ed. 2005, 44, 6700. Li, H.; Wang, Y.-Q.; Deng, L. Org. Lett. 2006, 8, 4063. Terada, M.; Sorimachi, K. J. Am. Chem. Soc. 2007, 129, 292. (a) Jia, Y.-X.; Zhong, J.; Zhu, S.-F.; Zhang, C.-M.; Zhou, Q.-L. Angew. Chem., Int. Ed. 2007, 46, 5565. (b) Jia, Y.-X.; Zhong, J.; Zhu, S.-F.; Zhang, C.-M.; Zhou, Q.-L. Angew.Chem. 2007, 119, 5661. [R] (a) Whaley, W. M.; Govindachari, T. R. Organic Reactions Vol. 6, Wiley, New York, 1951, p. 151. (b) Cox, E. D.; Cook, J. M. Chem. Rev. 1995, 95, 1797. (c) Pictet, A.; Spengler, T. Ber. Dtsch. Chem. Ges. 1911, 44,2030. d) Tatsui, G. J. Pharm. Soc. Jpn. 1928, 48,453. [R] (e) Cox, E. D.; Cook, J. M. Chem. Rev. 1995, 95, 1797. (0 Kaufmann, T. New Methods

Chapter 6 Transformations of Carbocycles

65. 66. 67. 68. 69. 70. 71. 72. 73. 74. 75. 76.

77. 78. 79.

80. 81.

82.

83. 84. 85.

673

in the Asymmetric Synthesis of Nitrogen Heterocycles Research SignPost, Trivandrum, India, 2005, Ch. 4, 99. Kawate, T.; Yamada, H.; Soe, T.; Nakagawa, M. Tetrahedron: Asymmetry 1996, 7(5), 1249. (a) Taylor, M. S.; Jacobsen, E. N. J. Am. Chem. Soc. 2004, 126, 10558. (b) Mergott, D. J.; Suend, S. L.; Jacobsen, E. N. Org. Lett. 2008,10, 745. Raheem, I. T.; Thiara, P. S.; Peterson, E. A.; Jacobsen, E. N. J. Am. Chem. Soc. 2007,129, 13404. Petersen, E.; A.; Jacobsen, E. N. Angew. Chem., Int. Ed. 2009, 48, 6328. Raheem, I. T.; Thiara, P. S.; Jacobsen, E. N. Org. Lett. 2008,10, 1577. (a) Klausen, R. E.; Jacobsen, E. N. Org.Lett. 2009, / / , 887. (b) Gahsesan, A.; Heathcock, C. H. Tetrahedron Lett. 1993, 3, 439. Seayad, J.; Seayad, A. M.; List, B. J. Am. Chem. Soc. 2006, 128, 1086. Wanner, M. J.; van der Haas, R. N. S.; de Cuba, K. R.; van Maarseveen, J. H.; Hiemstra, H. Angew. Chem., Int. Ed. 2007, 46, 7485. Jensen, K. B.; Thorhauge, J.; Hazell, R. G.; Jorgensen, K. A. Angew.Chem., Int. Ed. 2001, 40, 160. (a) Halland, N.; Velgaard, T.; J0rgensen, K. A. J. Org. Chem. 2003, 68, 5067. (b) Halland, T.; Hansen, T.; Jergensen, K. A. Angew. Chem., Int. Ed. 2003, 42, 4955. Zhuang, W.; Hansen, T.; Jergensen, K. A. Chem. Commun. 2001, 347. (a) Zhou, J.; Tang, Y. J. Am. Chem. Soc. 2002, 124, 9030. (b) Zhou, J.; Ye, M.-C; Huang, Z.; Tang, Y. J. Org. Chem. 2004, 69, 1309. (c) Zhou, J.; Tang, Y. Chem. Commun. 2004, 432. (d) Ye, M.-C; Li, B.;Zhou, J.; Sun, X.-L.; Tang, Y. J. Org. Chem. 2005, 70, 6108. (e) Similar results have just been reported by Fu using an optimized BOX catalyst bearing a ßaryl-substituted alkylidene linker on the ligand, see Sung, Y. J.; Li, N.; Zheng, Z.-B.; Liu, L.; Yu, Y. B.; Qin, Z.-H.; Fu, B. Adv. Synth. Catal. 2009, 351, 3113. Evans, D. A.; Rovis, T.; Kozlowski, M. C; Tedrow, J. S. J. Am. Chem. Soc. 1999,121, 1994. Rasappan, R.; Hager, M.; Gissibl, A.; Reiser, O. Org. Lett. 2006, 8, 6099. (a) Bandini, M.; Melloni, A.; Tommasi, S.; Umani-Ronchi, A. Helv. Chem. Acta 2003, 86, 3753-3763. (b) Bandini, M.; Fagioli, M.; Melchiorre, A. M.; Umani-Ronchi, A. Tetrahedron Lett. 2003, 44, 5843-5846. (e) Bandini,M.; Fagioli, M.; Garavelli, M.; Melloni, A.; Trigari, V.; Umani-Ronchi, A. J. Org. Chem. 2004, 69, 7511-7518. (d) Herrera, R. P.; Sgarzani, V.; Bernardi, L.; Ricci, A. Angew. Chem., Int. Ed. 2005, 44, 6576. Palomo, C; Oiarbide, M.; Kardak, B. G.; Garcia, J. M.; Linden, A. J. Am. Chem. Soc. 2005, 727,4154. (a) Evans, D. A.; Scheldt, K. A.; Fandrick, K. R.; Lam, H. W.; Wu, 3.J. Am. Chem. Soc. 2003, 125, 10780. (b) Evans, D. A.; Fandrick, K. R.; Song, H.-i.J. Am. Chem. Soc. 2005, 127, 8942. (c) Evans, D. A.; Fandrick, K. R. Org. Lett. 2006, 5, 2249. (d) Evans, D. A.;Fandrick, K. R.; Song, H.-J.; Scheldt, K. A.; Xu, K.J. Am. Chem. Soc. 2007,129, 10029. (e) Evans has also shown this methodology to applicable to the preparation of substituted 2substituted indoles; see reference 81d. (f) Boersma, A. J.; Feringa B. L.;Roelfes, G. Angew. Chem., Int. Ed. 2009, 48, 3346. (a) Paras, N. A.; MacMillan, D. W. C. J. Am. Chem. Soc. 2001,123,4370. (b) Austin, J. F.; MacMillan, D. W. C. J. Am. Chem. Soc. 2002,124, 1172. (c) Paras, N. A.; MacMillan, D. W. C. J. Am. Chem. Soc. 2002, 124, 7894. (d) Huang, Y.; Walji, A. M.; Larsen, C. H.; MacMillan, D. W. C. J. Am.Chem. Soc. 2005, 127, 15051. (e) Hong, L.;Wang, L.; Chen, C; Zhang, B.; Wang, R. Adv. Synth. Catal. 2009, 351,772. (f) Austin, J. F.; Kim, S.-G.; Sinz, C. J.; Xiao, W.-J.; MacMillan, D. W. C. Proc. Nati. Acad. Sci. 2004,101, 5482. (g) King, H. D.; Meng, Z.; Denhart, D.; Mattson, R.; Kimura, R.; Wu, D.; Gao, Q.; Macor, J. E. Org. Lett. 2005, 7, 3437. (h) Li, C.-F.; Liu, H.; Liao, J.; Cao, Y.-J.; Liu, X.-P.; Xiao, W.-J. Org. Lett. 2007, 9, 1847. Li, C.-F.; Liu, H.; Liao, J.; Cao, Y.-J.; Liu, X.-P.; Xiao, W.-J. Org.Lett. 2007, 9, 1847. (a) Blay, G.; Fernandez, I.; Pedro, J. R. Adv. Synth. Catal. 2009, 351, 2433. (b) Blay, G.; Fernandez, I.; Pedro, J. R.; Vila, C. Org. Lett. 2007, 9, 2601. (a) Tang, H.-Y.; Lu, A.-D.; Zhou, Z.-H.; Zhao, G.-F.; He, L.-N.; Tang, C. C. Eur. J. Org. Chem. 2008, 1406. (b) Chen, W.; Du, W.; Yue, L.; Li, R.; Wu, Y.; Ding, L.-S.; Chen, Y.-C. Org. Biomol. Chem. 2007, 5, 816. (c) Bartoli, G.; Bosco, M.; Carlone, A.; Pesciaoli, F.; Sambri, L.; Melchiorre, P. Org. Lett. 2007, 9, 1403. (d) Li, D.-P.; Guo, Y.-C; Ding, Y.;

674

Name Reactions for Carbocyclic Ring Formations Xiao, W.-J. Chem. Commun. 2006, 799. (e) Zhou, W.; Xu, L.-W.; Li, L.;Yang, L.;.Xia C.-G. Eur. J. Org. Chem. 2006, 5225.

Chapter 6 Transformations of Carbocycles

6.3

675

Houben-Hoesch Reaction

Richard J. Mullins and Matthew C. O'Reilly 6.3.1

Description

The electrophilic substitution of an activated nitrile onto an aromatic ring is known as the Houben-Hoesch reaction. The resulting imine is immediately hydrolyzed to yield the corresponding ketone. The reaction requires a Lewis acid and/or a protic acid, and results in arylketone products analogous to those which might be obtained under related Friedel-Crafts acylation conditions. OH

Jά0Η 6.3.2

1.CH3CN, ZnCI2 HCI, Et20 Z H2

°

OH

0

HO^ ^ O H

Historical Perspective

The Friedel-Crafts reaction, one of the more important and useful organic transformations, was discovered in 1877 by Charles Friedet and James Crafts. This class of reactions is generally thought to include all electrophilic alkylations and acylations of aromatic rings promoted by Lewis acids (traditionally A1C13 or FeCl3). Due to their synthetic utility, Friedel-Crafts reactions have been extensively studied and used across a broad and diverse area of chemical research. In 1898, Ludwig Gatterman reported the Lewis acid promoted reaction of hydrocyanic acid and benzene to produce aromatic aldehydes in a reaction that now bears his name.1 The related electrophilic substitution of an activated nitrile onto an electron-rich aromatic ring was first reported in 1915 by the German chemist Kurt Hoesch,2 who later served as the biographer of the legendary chemist Emil Fischer.3 The original paper details the reaction of phloroglucinol with a number of alkyl and aryl nitriles, the products of which are still being used in modern synthetic efforts. In 1926, Josef Houben, following a stint in the military during which he served as head of the war laboratory4 and extended and generalized the reaction discovered by Hoesch while at the Biologische Reichsanstalt in Berlin.5 Known mostly for his contribution to the Houben-Weyl Methods of Organic Chemistry reference series, his work on the title reaction earned him the honor of having it named

Name Reactions for Carbocyclic Ring Formations

676

after him. For a more thorough discussion of the history of the HoubenHoesch reaction, the reader is directed to an excellent review.6 6.3.3

Mechanism

The Houben-Hoesch reaction proceeds via a straightforward electrophilic aromatic substitution mechanism. After protonation or Lewis acid activation of the alkyl nitrile, nucleophilic attack by the electron-rich aromatic ring produces the resonance stabilized intermediate 1. Elimination of H+ regenerates the aromatic ring, resulting in the imine 2, which is rapidly hydrolyzed to produce the aryl ketone 3. 7

R-CEN-H

R-CEN

OH

NH

II

--

OH

NH

OH

O

Although the mechanism above is considered generally correct, there have been multiple studies, both theoretical and experimental, which have focused on the more subtle aspects of the mechanism. These studies focus mainly on the exact identity of the electrophilic species that is attacked in the first step. The structure of the reactive intermediate depends highly on the conditions utilized in the reaction as well as the particular aromatic species undergoing the transformation. For example, with an electron-rich species, it is generally thought that activation by Lewis acid or protic acid to produce the intermediate cation is sufficient to allow the reaction to occur.16 An alternate species 5 is suggested to be the electrophile when a hydrated Lewis acid is used in the reaction.16 Other authors have suggested the initial formation of a 1,3,5-triazinium salt, such as 4, which then acts as the active electrophile when the Houben-Hoesch reaction is run using triflic acid as catalyst.11 Finally, when benzene itself is used in the Houben-Hoesch, or the related Gattermann reaction, it is thought that the protonated nitrile is insufficiently electrophilic for the reaction to occur and that a dicationic species is in fact, the electrophilic species in the reaction.12'13

Chapter 6 Transformations of Carbocycles

677

R

2 CF3SO3

6.3.4

"lex

OH CF3SO3H

R-ΟΞΝ

HZnCI2OH

R

ZnCU

Variations and Improvement

2-Aminophenyl ketones have found utility as starting materials for the synthesis of 1,4-benzodiazepines, as well as several other important classes of drugs. Seeking an efficient and regioselective method for synthesis of this class of molecule, Sugasawa and co-workers used BCI3 to direct the orthoacylation of aniline, overcoming the typical difficulties associated with this particular Friedel-Crafts/Houben-Hoesch reaction.17 Specifically, the high reactivity of anilines, as well as their propensity to direct electrophilic substitution at the para-position, are both remedied using this technique. As shown, precomplexation of TV-methyl aniline (6) and BCI3 results in 7, which upon treatment with benzonitrile provides 9 after subsequent hydrolysis in high yield, gave exclusively as the ori/20-regioisomer. The regioselectivity is rationalized as arising from the cyclic transition state 8.17-19 This reaction has found expanded utility in recent synthetic endeavors, using a variety of electrophilic coupling partners in addition to nitriles, and is generally known as the Sugasawa reaction. NH

BCI3, benzene

BCI ^ 2

PhCN, 100°C

80 °C, 2 h

ΡΪΚ . Ν .

BCI2

PlK - N NaOH, H 2 0 87%

6.3.5

»

Synthetic Utility

For a complete description of synthetic utility of the Houben-Hoesch reaction before 1970 as well as some mechanistic discussions, the reader is directed to an excellent review on the subject.6 The Houben-Hoesch reaction has been widely used for the synthesis of a number of interesting

678

Name Reactions for Carbocyclic Ring Formations

compounds.20-25 Because of the relatively low electrophilicity of nitriles as compared to other carboxylic acid derivatives, the majority of useful Houben-Hoesch reactions are conducted with very electron-rich aromatic rings. In addition, due to the strong conditions required by the reaction, it is most often utilized in the early stages of a synthesis. As such, the utility of the Houben-Hoesch is not exclusively in the product of the reaction itself, but the manner in which the reaction is used to achieve the synthesis of a more complex target. For instance, a key step in the synthesis of flavonoid 12 is a Houben-Hoesch reaction.26 In one of the more common applications of this reaction, upon treatment of phloroglucinol (10) and acetonitrile with ZnCh and HC1, aryl ketone 11 is produced in good yield. OH O

CH3CN ZnCI2, HCI 76%

HO' ^ ^OH 11 OCH3

H 3 co

Owing to the high nucleophilicity of phloroglucinol (10), it has been been widely used as a coupling partner in the Houben-Hoesch reaction.27-38 An example of this is illustrated in Wandless and co-workers' synthesis of flavonol derivatives to be used as probes of biological processes.33 After dissolving phloroglucinol (10) and benzoyloxyacetonitrile in diethyl ether, treatment with HCI and subsequent aqueous workup resulted in the preparation of 13 in high yield. Similar processes using the related electronrich aromatics resorcinol and orcinol have been used in syntheses of modified flavonoids39 and benzoxanthones.40 The microwave-promoted Houben-Hoesch reaction in an ionic liquid has also recently been reported, using phloroglucinol as the aromatic species.41 Bn0CH CN

^ ,

HCI, Et20 91%

OH O

ΧΧ^ΟΒπ

ί Τ Η Ο ^ ^ Ό Η 13

Chapter 6 Transformations of Carbocycles

679

The Houben-Hoesch reaction of phloroglucinol has been elegantly used by Rama Rao and co-workers in a concise synthesis of the chromanol moiety of the antiHIV agent, calanolide A.42 As shown below, the chiral, non-racemic nitrile 14 is reacted with phloroglucinol (10) under standard Houben-Hoesch conditions to yield the ketone 15. Although the yield was modest (25%), the efficiency of this one-pot process offers significant advantages over previous methods for making similar compounds.

H3C,

OH ^CN

+

HC-

Y"y

.^.JDH

1.ZnCI 2 , HCI

Y

2. H 2 0, reflux

Et2ofrt

u

H3rC,

π

μ Ο γΛ ^ Οη Η

T

T

°15°H

In the same work, an intramolecular Houben-Hoesch was efficiently carried out to produce 16. Notable in this instance is the improved yield of this ring-forming transformation. H3C>.Ov^^.OCH3 I N Ί

y C N OCH

1.ZnCI 2 , HCI Et,0, rt

k

2. H 2 0, reflux 89o/o

3

HoCL· XL ^ ^ H3C

O

16

^OCH·,

OCH3

As long as the nucleophilic partner is substituted with electrondonating substituents, the Houben-Hoesch reaction has broad scope. This is most directly illustrated by the work of Parmar and co-workers who used Houben-Hoesch conditions for the synthesis of a large number of benzyl phenyl ketones. The Houben-Hoesch reaction has found synthetic utility not only with substituted benzene derivatives but also with other π-excessive heterocycles. An impressive example is provided in efforts directed toward the synthesis of novel 2-[5-aroylpyrrolo]alkanoic acids, for evaluation of their potential analgesic and antiinflammatory activities.44 Treatment of substituted pyrrole 17 and 3-cyanopyridine (18) with acid in dry chloroform resulted in the preparation of 19 in good yield. H3C C0 2 Et \—/

^i ti,co2E, ♦ Nf ^O N CH 3

^

17

N

18

C N

HCI, CHCI3 2h 60%

Name Reactions for Carbocyclic Ring Formations

680

The Houben-Hoesch has also been used in reactions with indoles.45'46 As a representative example, dimethoxyindole 20 is reacted with benzylcyanide under acidic conditions to produce the indole 21 which has been acylated at the 7-position.47 The SnCU-mediated Houben-Hoesch acylation of indole at the 3-position has also been reported to proceed in high yield and with exclusive regioselectivity.48 CI

CI \ N

PhCH2CN, HCI MeO

THF 43%

Me0

)

T

H Th 21

Issues of regioselectivity in the Houben-Hoesch and related FriedelCrafts reactions have been studied extensively. As is common with a majority of electrophilic aromatic substitution reactions, substitution typically occurs ortho or para to electron-donating substituents, with issues of steric strain playing a role in the relative ratio of ortho and para products. In many of the Houben-Hoesch reactions discussed thus far, a single major regioisomer was produced, whether because of some particular electronic or steric effect, which directed substitution in that way or because the aromatic partner in the reaction was such that substitution at one or more positions would result in the same product. Although para-substituted products are typically easier to produce via these reactions, there has been substantial interest in achieving exclusive ort/zo-substitution, while maintaining high yields. One of the first observations of competitive ori/jo-acylation in the Houben-Hoesch reaction came from the Johnston laboratories, where the reaction of phenol and acetonitrile with AlCb resulted in approximately equivalent amounts of the ortho- and para-isomers of the acetophenone product. While the yield of both isomers was low, perhaps owing to the diminished reactivity of the aromatic ring possessing only one electrondonating substituent, a useful strategy for directing substitution to the orthoposition emerged from these studies.49 Coordination of the Lewis acid with the phenolic oxygen and the nitrile nitrogen give complex 22, which directs substitution to the or//?oposition. It was this same rationale that has been so effectively applied in what has become known as the Sugasawa reaction for the or/Ao-acylation of anilines and phenols.17-19'50

681

Chapter 6 Transformations of Carbocycles

OPh "Al-OPh i ~

N

'/ CH 3 22

The Sugasawa modification has been effectively used in the synthesis of a large number of biologically interesting molecules.51-53 In particular, the 2-aminophenyl ketone products of the Sugasawa reaction can be readily transformed into indoles via a method, which was also developed by Sugasawa and co-workers.54-56 This method was impressively demonstrated in the total synthesis of (±)-dragmacidin.57 Specifically, dibromoaniline 23 and chloroacetonitrile (24) were coupled using BCI3 and T1CI4 to produce ketone 25 in very high yield. Conversion to indole 26 was subsequently effected by treatment of 25 with NaBH4 in refluxing dioxane. In related work, the synthesis of 2-substituted indoles featured a Sugasawa modified Houben-Hoesch reaction for preparation of the substituted 2'-amino-2chloroacetophenone starting materials.58'59 OCH-,

NH 2

+

^^^ CI^XN 24

CH3O

BCI3, TiCI4 CH2CI2

*■ reflux, 1.5 h

O

Br

NaBH 4 1,4-dioxane/H20 reflux, 4h 90%

Br

The Sugasawa modification has been used by Houpis and co-workers for the synthesis of the novel reverse transcriptase inhibitor 29.6 In this example, cyclopropyl nitrile was coupled with p-chloroaniline (27) using BCI3 and GaCU as the second Lewis acid. Following an acidic workup, ketone 28 was isolated in 74% yield, along with a small amount (~ 7%) of a product arising from cyclopropane opening.

682

Name Reactions for Carbocyclic Ring Formations

NH, CI

BCI3, GaCI3 PhCI, 100°C 20 h

27

The use of GaC^ in lieu of the more standard Lewis acid AICI3, was a result of previous studies by Houpis and co-workers, which delineated the role of the second Lewis acid in the Sugasawa modification.19 NMR studies suggest the presence of supercomplex 30 upon mixing of the respective aniline, nitrile, BCI3 and a second Lewis acid, such as GaCb. The role of the second Lewis acid seems to be to stabilize, and therefore make more favorable, the formation of the supercomplex. As such, Lewis acids with higher affinities for chloride ion should shift the equilibrium to the supercomplex 30, enabling more efficient ori/20-acylation. In all cases screened, the use of GaCU under milder conditions resulted in higher yields thanAlCh. 19

BCI,

N H Ή

+

R-CEN-GaCI3

+ .BC,2 GaCU H H 30

An alkylnitrilium variant of the Houben-Hoesch reaction was used in the synthesis of 11-hydroxy-O-methylsterigmatocystin (34).61 The preparation of 34 was sought to investigate the role of cytochrome P-450 in the biosynthesis of aflatoxin, a widespread food contaminant and environmental carcinogen. As demonstrated below, nitrilium salt 31 is coupled with 32 to produce 33 in high yield.

Chapter 6 Transformations of Carbocycles

683 OPiv

OH /L/COOMe

N'

ΡίνΟγΙγ^ SbClfi

XX

MeO

31

OH

MeO CH2CI2

32

90%

OH COOMe

A similar and creative use of an in situ generated alkylnitrilium was demonstrated in the simple, one-pot synthesis of 2-benzazapine derivatives, of interest due to their presence in many pharmaceutically active agents.62 Occurring by way of simultaneous Ritter and Houben-Hoesch reactions, the transformation proceeds to form new C-N and C-C bonds, respectively. Mechanistically, resonance-stabilized carbocation 36, formed by protonation of the allylic alcohol in 35, is attacked by propionitrile to produce nitrilium cation 37. The Houben-Hoesch reaction then occurs with the nitrilium species to complete the formation of the benzazapine 38, in high yield. The reaction has proven general for preparation of a number of 2-benzazepine derivatives in moderate to good yields.

MeO

C0 2 Et

OMe

C0 2 Et

OMe 36

,C0 2 Et

150°C, 6h 74%

35

MeO

EtCN, CH3SO3H

MeO

MeO EtCN

,C0 2 Et

684

Name Reactions for Carbocyclic Ring Formations

The intramolecular attack of a nitrilium ion is a key step in the Meerwein quinazoline synthesis.63 A recent example of this reaction can be seen in the synthesis of 4-(Arr/V-dimethylamino)-2-arylquinazolines, as demonstrated below.64 Treatment of imidoyl chloride 39 with NJldimethylcyanamide (40) followed by TiCU results in the formation of intermediate 41. Mechanistically, after the production of the likely intermediate nitrilium ion 41, the Houben-Hoesch reaction occurs to give quinazoline 42. A related procedure has been utilized for the synthesis of phenanthridines.65 1.

PH 3 NEC-N 40 CH3 » benzene

,N-CH3

2. TiCI4, 78%

39

\

6.3.6 Experimental Houben-Hoesch reaction 1.CH3OCH2CN ZnCI2, Et 2 0, 0 °C OH

OH O OCHq 1

2. H 20, reflux 80%

2'4'6'-Trihydroxy-2-methoxyacetophenone (43)29 Anhydrous phloroglucinol (10) (6.3 g, 50 mmol) was dissolved in dry ether (60 mL). Anhydrous ZnCl2 (1.8 g, 13 mmol) and methoxyacetonitrile (3.7 mL, 50 mmol) were added. The flask was placed in an icebath. Anhydrous HC1 gas was bubbled through the solution for 2 h under stirring. The ketimine hydrochloride which precipitated from the solution was filtered off,

Chapter 6 Transformations of Carbocycles

685

washed twice with a small amount of dry ether, dissolved in water and refluxed for 30 min. After cooling, a pink crystalline product precipitated which was recrystallized from water. Yield: 80%.

BCI3, TiCI4 CH2CI2

reflux, 1.5 h 90%

2-Amino-3,4-dibromo-6-methoxy-a-chloroacetophenone (25)58 To a stirred solution of 23 (32 g, 0.17 mol) in CH2CI2 (300 mL) cooled in an ice bath was added dropwise successively, boron trichloride (1 M in CH2CI2, 180 mL, 0.18 mol), chloroacetonitrile (14.3 g, 0.19 mol), and titanium tetrachloride (1 M in CH2CI2, 190 ml, 0.19 mol). The resulting mixture was refluxed for 1.5 h. After being cooled to room temperature, the mixture was carefully poured into a mixture of ice and 20% HC1 (700 mL). The organic solvent was distilled. The residue was heated on a water bath (90 °C) for 30 min. After the solution was cooled to room temperature, the solid was filtered off and partitioned between ether (1.4 L) and 1 N NaOH (500 mL). The organic layer was separated and washed with brine, dried over Na2SC>4, and concentrated. The resulting solid was recrystallized from ethanol to afford 25 (55 g) in 90% yield. 6.3.6

References

1. 2. 3. 4. 5. 6.

Gatterman, W.; Berchelmann, W. Ber. 1898, 31, 1765-1769. Hoesch, K. Ber. 1915, 48, 1122-1133. [R] Fischer, H. O. L. Annu. Rev. Biochem. 1960, 29, 1-14. [R] Ronge, G. In Neue Deutsche Biographie, Dunker & Humblot, Berlin, 1972, p. 659. Houben, J. Ber. 1926, 59, 2878-2891. [R] Ruske, W. In Friedel-Crafts and Related Reactions, Olah, G. A. ed.; Interscience, New York, 1964, 383-497. [R] Li, Jie J. Name Reactions: A Collection of Detailed Reaction Mechanisms, SpringerVerlag, Telos, N.Y., 2002, p. 200. Alagona, G.; Tornasi, J. J. Mol. Struct. 1983, 91, 263-288. Jeffrey, E. A.; Satchell, D. P. N. J. Chem. Soc. B. 1966, 579-586. Fodor, G.; Nagubandi, S. Tetrahedron 1979, 36, 1279-1300. Amer, M. I.; Booth, B. L.; Noori, G. F. M.; Proenca, M. F. J. R. P. J. Chem. Soc, Perkin Trans. 1 1983, 1075-1082. Yato, M; Ohwada, T.; Shudo, K. J. Am. Chem. Soc. 1991, 113, 691-692. Sato, Y.; Yato, M.; Ohwada, T.; Saito S.; Shudo, K. J. Am. Chem. Soc. 1995, 117, 30373043. Booth, B. L.; Noori, G. F. M. J. Chem. Soc, Perkin Trans. 1 1980, 2894-2900.

7. 8. 9. 10. 11. 12. 13. 14.

686 15. 16. 17. 18. 19. 20. 21. 22. 23. 24. 25. 26. 27. 28. 29. 30. 31. 32. 33. 34. 35. 36. 37. 38. 39. 40. 41. 42. 43. 44. 45. 46. 47. 48. 49. 50. 51. 52. 53. 54.

Name Reactions for Carbocyclic Ring Formations Stang, P. J.; Anderson, A. G. J. Am. Chem. Soc. 1978, 100, 1520-1525. Li, S.; Li, Y.; Zheng, H. Eur. J. Mass Spectrom. 2005, 11, 389-392. Sugasawa, T.; Toyoda, T.; Adachi, M.; Sasakura, K. J. Am. Chem. Soc. 1978, 100, 48424852. Toyoda, T.; Sasakura, K.; Sugasawa, T. /. Org. Chem. 1981, 46, 189-191. Douglas, A. W.; Abramson, N. L.; Houpis, I. N.; Karady, S.; Molina, A.; Xavier, L. C; Yasuda,N. Tetrahedron Lett. 1994, 35, 6807-6810. Màk, M.; Nógràdi, M.; Szöllösy, A. Tetrahedron 2006, 62, 8425-8429. Beck, G.; Bergmann, A.; Kebeler, A.; Wess, G. Tetrahedron Lett. 1990, 31, 7293-7296. Shokol, T. V.; Turov, V. A.; Turov, A. V.; Krivokhizha, N. V.; Semenyuchenko, V. V.; Khilya, V. P. Chem. Heterocycl. Compd, 2005, 41, 1411-1418. Ahluwalia, V. K.; Kumar, D.; Gupta, M. C. Indian J. Chem., Sect B 1978,16B, 574-578. Cameron, D. W.; Deutscher, K. R.; Feutrill, G. I.; Hunt, D. E. Aust. J. Chem. 1982, 35, 14511461. Tamiya, J.; Sorensen, E. J. Tetrahedron 2003, 59, 6921-6932. Chengmin, Z.; Fuchu, L.; Hongyou, Z. Chinese Journal ofAppi. Chem. 1998, 15, 68-69. FriSiic, T.; Drab, D. M.; MacGillivray, L. R. Org. Lett. 2004, 6, 4647^1650. Van der Schyf, C. J.; Dekker, T. G.; Fourie, T. G.; Snyckers, F. O. Antimicrob. Agents Chemother. 1986, 30, 375-381. Boers, F.; Deng, B.-L.; Lemière, G.; Lepoivre, J.; De Groot, A.; Dommisse, R.; Vlietinck, A. Arch. Pharm. Pharm. Med Chem. 1997, 330, 313-316. Bass, R. J. J. Chem. Soc, Chem. Comm. 1976, 78-79. Mustafa, K. A.; Kjaergaard, H. G.; Perry, N. B.; Weavers, R. T. Tetrahedron 2003, 59, 6113-6120. Zheng, X.; Meng, W.-D.; Qing, F.-L. Tetrahedron Lett. 2004, 45, 8083-8085. Tanaka, H.; Stohlmeyer, M. M.; Wandless, T. J.; Taylor, L. P. Tetrahedron Lett. 2000, 41, 9735-9739. Howells, H. P.; Little, J. G. J. Am. Chem. Soc. 1932, 54, 2451-2453. Shriner, R. L.; Grosser, F. J. Am. Chem. Soc. 1942, 64, 382-384. Urgaonkar, S.; Shaw, J. T. J. Org. Chem. 2007, 72,4582^t585. Hastings, J. M.; Hadden, M. K.; Blagg, B. S. J. J. Org. Chem. 2008, 73, 369-373. Beney, C; Mariotte, A.; Boumendjel, A. Heterocycles 2001, 55, 967-972. Arkhipov, V. V.; Smirnov, M. N.; Khilya, V. P. Chem. Heterocycl. Compd. 1997, 33, 515519. Kjaer, D.; Kjaer, A.; Risbjerg, E. J. Chem. Soc, Perkin Trans. 1 1983, 2815-2820. Hakala, U.; Wähälä, K. Tetrahedron Lett. 2006, 47, 8375-8378. Rama Rao, A. V.; Gaitonde, A. S.; Prakash, K. R. C; Rao, S. P. Tetrahedron Lett. 1994, 35, 6347-6350. Parmar, V. S.; Pati, H. N.; Azim, A.; Kumar, R.; Himanshu, K. S. B..; Prasad, A. K.; Errington, W. Bioorg. Med. Chem. 1998, 6, 109-118. Chang, M. N.; Biftu, T.; Boulton, D. A.; Finke, P. E.; Hammond, M. L.; Pessolano, A. A.; Zambias, R. A.; Bailey, P.; Goldenberg, M.; Rackham, A. Eur. J. Med. Chem, Chim. Ther. 1986,21, 363-369. Albrecht, R.; Heindl, J.; Loge, O. Eur. J. Med. Chem. 1985, 20, 57-60. Norcini, G.; Allievi, L.; Bertolini, G.; Casagrande, C; Miragoli, G.; Santangelo, F.; Semeraro, C. Eur. J. Med. Chem. 1993, 28, 505-511. Black, D. S.; Kumar, N.; Wahyuningsih, T. D. ARK1VOC 2008, 6, 42-51. Ottoni, O.; Neder, A., Dias, A. K. B.; Cruz, R. P. A.; Aquino, L. B. Org. Lett. 2001, 3, 10051007. Johnston, H. W. J. Org. Chem. 1959, 25,454-455. Bigi, F.; Maggi, R.; Sartori, G.; Casnati, G.; Bocelli, G. Gazz. Chim. hai. 1992, 122, 283289. Nourry, A.; Legoupy, S.; Huet, F. Tetrahedron 2008, 64, 2241-2250. Atechian, S.; Nock, N.; Norcross, R. D.; Ratni, H.; Thomas, A. W.; Verron, J.; Masciadri, R. Tetrahedron 2007, 63, 2811-2823. Merlic, C. A.; Motamed, S.; Quinn, B. J. Org. Chem. 1995, 60, 3365-3369. Sugasawa, T.; Adachi, M.; Sasakura, K.; Kitagawa, A. J. Org. Chem. 1979, 44, 578-586.

Chapter 6 Transformations of Carbocycles 55. 56. 57. 58. 69. 60. 61. 62. 63. 64. 65.

687

Wager, C. A. B.; Miller, S. A. J. Label. Compd. Radiopharm. 2006, 49, 615-622. Nimtz, M.; Häfelinger, G. Liebigs Ann. Chem. 1987, 9, 765-770. Jiang, B.; Smallheer, J. M.; Amaral-Ly, C.; Wuonola, M. A. J. Org. Chem. 1994, 59, 68236827. Pei, T.; Chen, C.-y.; Dormer, P. G.; Davies, I. W. Angew. Chem. Int. Ed. 2008, 47,42314233. Pei, T.; Tellers, D. M.; Streckfuss, E. C; Chen, C.-y.; Davies, I. W. Tetrahedron 2009, 65, 3285-3291. Houpis, I. N.; Molina, A.; Douglas, A. W.; Xavier, L.; Lynch, J.; Volante, R. P.; Reider, P. J. Tetrahedron Lett. 1994, 35, 6811-6814. Udwary, D. W.; Casillas, L. K.; Townsend, C. A. J. Am. Chem. Soc. 2002, 124, 5294-5303. Basavaiah, D.; Satyanarayana, T. Chem. Commun. 2004, 32-33. Meerwein, H.; Laasch, P.; Mersch, R.; Netwig, J. Chem. Ber. 1956, 89, 224-238. Zielinski, W.; Kudelko, A.; Holt, E. M. Heterocycles 1996, 43, 1201-1209. Petterson, R. C; Bennett, J. T.; Lankin, D. C; Lin, G. W.; Mykytka, J. P.; Troendle, T. G. J. Org. Chem. 1974, 39, 1841-1845.

688

Name Reactions for Carbocyclic Ring Formations

6.4

K o l b e - S c h m i t t Reaction

Martin E. Hayes 6.4.1

Description ONa

0

R

OH O

i8 25o c

°- ° "

CJ

0Na

R

The Kolbe-Schmitt reaction is the carboxylation of phenolic salts, traditionally using carbon dioxide gas at elevated temperatures and pressures. Salicylic acids derived from or^o-carboxylation are most commonly obtained while the para-carboxylation and di-carboxylation products can also be prepared through judicious choice of counterions and reaction medium.1 6.4.2

Historical Perspective

r

salicylic Acid

acetylsalicylic Acid (Aspirin)

OH diflunisal

butylparaben

Kolbe was a student of Wöhler and later assistant to Bunsen, and he is credited with coining the term synthesis after the first preparation of acetic acid from carbon disulfide.3 He also made substantial contributions to the establishment of the modern theory of molecular structure during the mid1800s, including predicting the existence of secondary and tertiary alcohols prior to their first preparations.2 The Kolbe-Schmitt reaction, not to be confused with the Kolbe electrolysis reaction, remains the most direct method for preparing aromatic hydroxylacids and has been used extensively in the industrial synthesis of analgesic salicylates, including aspirin and diflunisal, and biocidic parabens, such as butylparaben. Rudolph Schmitt, a doctoral student of Kolbe's, introduced the use of a sealed pressure reactor, which allows for more reproducible and scalable yields of hydroxy acids.3

Chapter 6 Transformations of Carbocycles

689

6.4.3 Mechanism „® Θ -K 0'

o. \

ortho pathway

θ

,o~.

©

o K O' ,:K __

°

/

K

\

Θ

O

1,3-shift

The mechanism has been extensively studied, including isotopie labeling,4 spectroscopy,5 and ab initio calculations.6 There are a wide variety of conditions under which the Kolbe-Schmitt reaction can be executed along with several mechanistic subtleties,7 including the reversibility of the reaction pathway.8 However, the classical conditions9 involving combination of gaseous carbon dioxide with the potassium salt of phenol at temperatures up to 250 °C are believed to proceed via the addition of phenoxide to carbon dioxide to give a phenylcarbonate salt 2. This intermediate is then solvated by additional molecules of CO2 at elevated pressure.10 The solvated CO2 is attacked by the π-system and, depending on the size of the counterion,11 gives either or?/zo-substitution (4) orpora-substitution (6). The intermediates 4 and 6, can then tautomerize to the resulting salicylate (5) or paraben (7) salts.12

690

Name Reactions for Carbocyclic Ring Formations

Alternative mechanisms, including the combination of two molar equivalents of phenoxide with one mole of carbon dioxide,1 have been proposed, however spectroscopic and empirical observations along with ab initio calculations are consistent with the activation of CO2 via a phenylcarbonate salt such as 2. Recently developed modifications using super-critical CO213 and ionic liquids,14 however, may involve alternative mechanistic pathways as such reaction conditions have not yet been carefully examined. 6.4.4

Variations and Improvements

The original conditions15 employed by Kolbe involved the formation of sodium phenoxide through evaporation of a molar equivalent mixture of phenol and aqueous sodium hydroxide. The hygroscopic sodium phenoxide is then heated at 180 °C while a stream of carbon dioxide is passed over the molten salt. The mixture is then heated at 220-250 °C to give the dianion of salicylic acid along with carbon dioxide and phenol, both of which distill away from the reaction mixture. Under these conditions, only a 50% theoretical yield of salicylic acid can be realized and often less is isolated. The Schmitt modification16 introduces a pressure reactor, typically an autoclave, whereby excess phenol and carbon dioxide do not escape and are efficiently converted to the hydroxy acid product. Using anhydrous sodium phenoxide, obtained by treatment of phenol with sodium metal, allows for a nearly quantitative isolation of salicylic acid after acidification. While the reaction is sensitive to water, it can be run in a variety of solvents, including aromatics, dioxane, pyridine, and DMF or under solvent-free conditions. A significantly more convenient method for the preparation of hydroxy acids was disclosed by Marasse17 in which a phenol is combined with an excess of an anhydrous carbonate salt at elevated temperature and pressure. The reaction is limited to potassium, rubidium, and cesium carbonate, yet avoids the stepwise preparation of anhydrous phenoxide salts. Recently, aqueous conditions have also been disclosed, which obviate the 18

need for anhydrous carbonate reagents in some cases. Methods using microreactors19 and microwave heating20 have been described, which provide for significant increases in throughput21 for the preparation of simple aromatic hydroxy acids. Alternative reaction media such a supercritical CO2 and ionic liquids have also been incorporated as both solvents and reagents, which, if recycled, may provide further efficiencies in the flow process.

Chapter 6 Transformations of Carbocycles

6.4.5

691

Synthetic Utility

General Utility The regiochemical outcome of the reaction largely depends on the counterion and reaction media and has been extensively reviewed. In general, smaller counterions, such as sodium and lithium, favor orthosubstitution of the carboxy group, while larger counterions, like potassium, preferentially lead to para-substitution.24 The reaction can be extended to naphthalene ring systems to prepare o-hydroxynapthanoic acids in good yields. For example, the potassium salt of 2-napthanol (8) can be converted to 2-hydroxy-l-napthanoic acid (9) in 52% yield at 50 °C under 725 psi CO2.4 At higher temperatures, usually above 200 °C, isomerization to give various mixtures of 2-hydroxy-3napthanoic acid (10) and 2-hydroxy-6-napthanoic acid (11) is known to occur.23·25

Temperature

9

10

20 °C

52%

0%

230 °C

22%

33%

9%

The regiochemical outcome for substituted aromatics is also strongly influenced by field effects, with donating groups favoring ortho- and parasubstitution relative to the hydroxyl. For example, 3-aminophenol provides para-ammo salicylic acid (13) as the major product along with variable amounts of the corresponding isophthalic acid resulting from dicarboxylation. Similarly electron-withdrawing groups inhibit the overall reaction rate, as in the case of 3-nitrophenol.27 The rate of reaction is also subject to steric effects with alkyl substitutions meta to the hydroxyl acting as blocking groups for carboxyl substitution ortho to the hydroxyl.27'28 The reaction is also sensitive to the presence of oxygen with competitive

Name Reactions for Carbocyclic Ring Formations

692

dimerization to give the corresponding biaryl under aerobic reaction conditions.29 HoN

/ \ OH Ύ ^ ν

KOH then drying; Psi c ° 2 . 2 0 0 °c

725

80%

12 \ / ^ /OH ^ y

H2N^ ^ ^ JDH ΎΓ "*T ^^k/OH 13

Ö

q u i v K 2C0 3 " V ' V ' '.OH 750p-CQ,,180-C> \ ^ Q 2e

14

H

15 °

The reaction has been extended to a number of heterocycles, including hydroxy-pyridines where the 4-position relative to the ring nitrogen can be favored for carboxylation.1 Also the direct addition of carbon dioxide has been reported for several azoles devoid of a hydroxyl group. The azole nitrogen presumably forms an intermediate carbamate salt, which is subject to ring carboxylation and tautomerization to give carboxyazoles, such as 2This has also been demonstrated on pyrrolecarboxylic acid (17).30 imidazoles and benzimidazoles where the 2-position is selectively carboxylated.31 It is nteresting that the Kolbe-Schmitt reaction with indoles provides direct access to 3-carboxyindole (19), while organolithiummediated carboxylation affords the 2-carboxyindole (20),33 exclusively.

Qcvf \^^N H 20

OH

H ^N [I >

5 equiv KHC03 800psiCO 2 100 °C, H 2 0

16

4 l / 0

4

41%

n-BuLi, C0 2 ; f-BuLi then NH4CI .

70%

O X H HO^NpN ^--y 17

Chapter 6 Transformations of Carbocycles

693

Applications in the total synthesis of natural products OAc

Na, MeOH C 0 2 , 180 °C O. OH

21

22

86%

The Kolbe-Schmitt reaction has been used as a key step in natural product synthesis. The early syntheses of isotubaic acid (Rotenic acid) used a KolbeSchmitt reaction in the final step.34 Shriner and co-workers converted isotubanol (22) to its sodium salt under anhydrous conditions, then heated the phenoxide with solid carbon dioxide at 180 °C in a sealed reaction vessel to give an 86% yield of the natural product.35 Sheehan and co-workers also used the Kolbe-Schmitt reaction to prepare an early intermediate in the synthesis of gossypol where thymol is efficiently converted to o-thymotic acid in 65% yield. Applications in the synthesis of pharmaceuticals The Kolbe-Schmitt reaction made possible the first industrial synthesis of salicylic acid and then acetyl salicylic acid, as two of the most important and widely used analgesics in history.3 Schmitt is credited with establishing a scalable protocol for salicylic acid manufacture, which provided a cornerstone for the burgeoning German fine chemicals industry in the late 19th century. NH 2

isoamyl nitrite benzene, reflux

CS 2 , AICI3 Ac 2 0, reflux

51%

94%

24

triflouroperacetic acid Na 2 HP0 4 , CH 2 CI 2 95% 26

694

Name Reactions for Carbocyclic Ring Formations

K2C03, 3400 psi C0 2 250 °C, 6 h 81%

„OH

,0 H ! 29

Extensive research by T. Y. Shen and co-workers around salicylic acid analogs37'38 at Merck, Sharp & Dohme led to more potent and longer lasting salicylates, such as Diflunisal. The commercial synthesis of Diflunisal involves a Marasse modification of the Kolbe-Schmitt reaction using biaryl phenol 28 at 250 °C with 3400 psi C0 2 for 6 h to give 29 in 81% yield. The Kolbe-Schmitt reaction has also been used to prepare HIV integrase inhibitors39 where 8-hydroxyquinaldine (30) is converted to its corresponding quinalidic acid (31) in the course of cellular structure-activityrelationship studies. 1. KOH, PhMe, Dean-Stark » 2. C0 2 , DMF, 160 °C 22%

30

31

The use of alkyl parabens as biocides in food, drug, and cosmetics manufacture is widespread, despite controversial claims ° of links to certain cancers.41 Industrial syntheses of paraben esters use the Kolbe-Schmitt reaction, principally via the corresponding potassium phenoxide, which favors /?ara-carboxylation. A modification that strongly favors parasubtitution involves potassium ethylcarbonate as a base, which gives a 93% yield of 4-hydroxybenzoic acid (33) from phenol at 225 °C under an atmosphere of 25 atm CO2.42 Additional protocols using carboxylase enzymes under an atmosphere of CO243 and with supercritical CO2 4 have been reported to furnish para-carboxylation exclusively and in high yields.

σ

OH

32

1.1 equivKOC02Et 25atmC0 2 , 215 °C 93%

)

695

Chapter 6 Transformations of Carbocycles

6.4.6

Experimental

Preparation of 8-Hydroxy-7-quinaldic Acid (31)

-in

1. KOH, PhMe, Dean-Stark : : ► HO 2. C0 2 , DMF, 160 °C 22%

30

31

To a suspension of 8-hydroxyquinaldine (30, 29 g, 0.18 mol) in toluene (130 mL) was added potassium hydroxide (11.3 g, 0.20 mol). The stirred mixture was heated under reflux for 24 h, collecting the water of the reaction in a Dean-Stark trap. After the mixture cooled at 20 °C, DMF (100 mL) was added, and the Dean-Stark trap was replaced with a distillation column. The reaction mixture was progressively heated until most of the toluene had been distilled. When the temperature reached 140 °C, a stream of CO2 was passed into the solution and continued throughout the reaction. The distillation of the solvents was continued while the temperature was gradually raised to 160 °C. The reaction mixture was heated for 2 h at this temperature and then cooled to 20 °C. The stream of CO2 was stopped, and water (250 mL) was added. The solution was acidified to pH = 7 with concentrated HC1 and the mixture was extracted with ethyl acetate. The aqueous phase was acidified to pH = 4.2, and the precipitate was filtered, washed with water, and dried in vacuo. The crude acid was recrystallized in 2-propanol to give acid 31 (8.0 g, 22%) as yellow crystals: m.p. 206-208 °C. Preparation of /;ara-hydroxybenzoic acid (33)42

" ν 32

0 Η

1.1equivKOC02Et 25atmC0 2 , 215 °C 93%

A glass reactor placed in a steel autoclave was charged with phenol (2.35 g, 0.025 mol) and potassium ethyl carbonate (3.46 g, 0.027 mol). The autoclave was closed, and carbon dioxide was fed to a pressure of 25 atm in two steps. The reaction mixture was stirred at this pressure, and its temperature was raised for 6 h to 215 °C (heating rate 32 °C/h) and then kept at this temperature for 1 h. After cooling to room temperature, the reaction mixture was treated with water. The aqueous solution was treated with toluene to

696

Name Reactions for Carbocyclic Ring Formations

remove unreacted phenol and then acidified to give joara-hydroxybenzoic acid (3.21 g, 93% yield), m.p. = 214-216 °C. 6.4.7 References 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18. 19. 20. 21. 22. 23. 24. 25. 26. 27. 28. 29. 30. 31. 32. 33. 34.

[R] Lindsey, A. S.; Jeskey, H. Chem. Rev. 1957, 57, 583-620. [R] Meyer, E. V.; McGowan, G. A History of Chemistry from Earliest Times to the Present Day Being also an Introduction to the Study of the Science; MacMillan, London, 1906, pp. 323-332. [R] Rocke, A. J. The Quiet Revolution: Hermann Kolbe and the Science of Organic Chemistry, University of California Press, Berkeley, 1993, pp. 291-296, 304-309. Kosugi, Y.; Imaoka, Y.; Gotoh, F.; Rahim, M.; Matsui, Y.; Sakanishi, K. Org. Biomol. Chem. imi, /, 817-821. Hales, J. L.; Jones, J.; Lindsey, A. J. Chem. Soc. 1954, 3145-3151. Stanescu, I.; Achenie, L.E. Chem. Eng. Sci. 2006, 61, 6199-6212. Kosugi, Y.; Takahashi, K.; Imaoka, Y. J. Chem. Res. (S) 1999, 114-115. Rahim, M. A.; Matsui, Y.; Matsuyama, T.; Kosugi, Y. Bull. Chem. Soc. Jpn. 2003, 76, 21912195. Kolbe, H. J. Prakt. Chem. 1874, 10, 89-112. Markovic, Z.; Markovic, S.; Manojlovic, N.; Predojevic-Simovic, J. J. Chem. Inf. Model. 2007, 47, 1520-1525. Markovic, S.; Markovic, Z.; Begovic, N.; Manojlovic, N. Russ. J. Phys. Chem. A. 2007, 81, 1392-1397. Markovic, Z.; Markovic, S. J. Chem. Inf. Model. 2008, 48, 143-147. Iijima, T.; Yamaguchi, T. Tetrahedron Lett. 2007, 48, 5309-5311. Stark, A.; Huebschmann, S.; Sellin, M.; Kralisch, D.; Trotzki, R.; Onuschka, B. Chem. Eng. Tech. 2009, 32, 1730-1738. Kolbe, H.; Lautemann, E. Justus Liebigs Ann. Chem. 1860, 115, 157-206. Schmitt, R. J. Prakt. Chem. 1885, 31, 397^111. Baine, O.; Adamson, G. F.; Barton, J. W.; Fitch, J. L.; Swayampati, D. R.; Jeskey, H. J. Org. Chem. 1954, 79,510-514. Morinaga, N.; Uchigashima, M.; Rahim, M. A.; Onishi, K.; Takahashi, K.; Kosugi, Y. J. Chem. Soc. Jpn. 2002, 467. Hessel, V.; Hofmann, C; Lob, P.; Lohndorf, J.; Lowe, H.; Ziogas, A. Org. Proc. Res. Dev. 2005, 9, 479-489. Benaskar, F.; Hessel, V.; Krtschil, U.; Lob, P.; Stark, A. Org. Proc. Res. Dev. 2009, 13, 970982. Krtschil, U.; Hessel, V.; Reinhard, D.; Stark, A. Chem. Eng. Tech. 2009, 32, 1774-1789. Huebschmann, S.; Kralisch, D.; Hessel, V.; Krtschil, U.; Kompter, C. Chem. Eng. Tech. 2009, 32, 1757-1765. Rahim, M. A.; Matsui, Y.; Kosugi, Y. Bull. Chem. Soc. Jpn. 2002, 75, 619-622. Markovic, Z.; Markovic, S.; Begovic, N. J. Chem. Inf. Model2006, 46, 1957-1964. Markovic, Z.; Markovic, S.; Durovic, I. Monatsh. Chem. 2008, 139, 329-335. Doub, L.; Schaeffer, J. A.; Stevenson, O. L.; Walker, C. T.; Vanderbelt, J. M. J. Org. Chem. 1958, 23, 1422-1424. Wessely, F.; Benedikt, K.; Benger, H.; Prillinger, G. F. Monatsh. Chem. 1950, 81, 10711091. De, A. U.; Saha, B. P. J. Med. Chem. 1971, 14, 265-266. Chidambaram, M.; Sorenson, J. J. Pharm. Sei. 1991, 80, 810-811. Scott, J. W.; Focella, A.; Hengartner, U. O.; Parrish, D. R.; Valentine, D., Jr. Syn. Comm. 1980, 10, 529-540. Kempe, U.; Dockner, T.; Koehler, H. Patent Application EP0328955, 1989-08-23. Binder, H.; Koch, O. Pat. Appi. DEI 193946, 1965-06-03. Katritzky, A. R.; Akutagawa, K. Tetrahedron Lett. 1985, 26, 5935-5938. Reichstein, T.; Hirt, R. Helv. Chim. Acta. 1933, 16, 121-129.

Chapter 6 Transformations of Carbocycles

697

Shriner, R. L.; Witte, M. J. Am. Chem. Soc. 1941, 63, 1108-1110. Shirley, D. A.; Brody, S. S.; Sheehan, W. C. J. Org. Chem. 1957, 22,495^197. Jones, H.; Fordice, M. W.; Greenwald, R. B.; Hannah, J.; Jacobs, A.; Ruyle, W. V.; Walford, G. L.; Shen, T. Y. J. Med. Chem. 1978, 21, 1100-1104. Hannah, J.; Ruyle, W. V.; Jones, H.; Matzuk, A. R.; Kelly, K. W.; Witzel, B. E.; Holtz, W. J.; Houser, R. A.; Shen, T. Y. J. Med. Chem. 1978, 21, 1093-1100. Mekouar, K.; Mouscadet, J. F.; Desmaele, D.; Subra, F.; Leh, H.; Savoure, D.; Auclair, C; d'Angelo, J. J. Med. Chem. 1998, 41,2846-2857. Darbre, P.; Harvey, P. J. Appi Toxicol. 2008, 28, 561-578. Anderson, F. A. Int. J. Toxicol. 2008, 27 Suppl. 4, 1-82. Suerbaev, K. A.; Akhmetova, G. B.; Shalmagambetov, K. M. Russ. J. Gen. Chem. 2005, 75, 1498-1499. Aresta, M.; Quaranta, E.; Liberio, R.; Dileo, C; Tommasi, I. Tetrahedron 1998, 54, 8841— 8846. Dibenedetto, A.; Noce, R. L.; Pastore, C; Aresta, M.; Fragale, C. Envir. Chem. Lett. 2006, 3, 145-148.

Name Reactions for Carbocyclic Ring Formations

698

6.5

Vilsmeier-Haack Reaction

Brian Goess 6.5.1 Description When a dialkyl amide is treated with phosphorus oxychloride a VilsmeierHaack reagent (hereafter Vilsmeier reagent) is formed. Subsequent treatment with an electron-rich π system leads to substitution and formation of an intermediate iminium ion, which can be hydrolyzed to yield an aldehyde. The overall process is known as a Vilsmeier-Haack reaction (hereafter Vilsmeier reaction).1 R1 I ,2. Ν ^ , Η

R

Y

^

POCI 3

R 1

2

R

EDG-

γ ci

O

a Vilsmeier reagent 2

R N0_R1

EDG-

// \\ //

H2

°

// \

6.5.2 Historical Perspective As early as 1902 it was recognized that the combination of formanilide and phosphoryl chloride will formylate 1,3-dihydroxybenzene.2 Though the scope of the reaction was limited, this seminal result foreshadowed the 1925 discovery by Vilsmeier and colleagues that the reaction of Nmethylacetanilide and phosphoryl chloride yielded, among other things, 4chloro-1,2-dimethylquinolinium chloride.3 CH 3 N^CH3

To

P0CI 3

Subsequent investigations indicated that a key intermediate in this reaction was an iminium salt that reacts with aromatic compounds, such as jV,7V-dimethylaniline, to yield products of aromatic substitution.4 At that time

Chapter 6 Transformations of Carbocycles

699

there was little definitive evidence for the identity of X in the following scheme. 1) CH 3 N

N(CH3)2

CH 3 H

POCI3

o

2)H20

x

CHO

It was then quickly discovered that a number of acid chlorides, including thionyl chloride, oxalyl chloride, phosgene, and carbonyl chloride were capable of reacting with a JV,JV-dialkylformamides to form a weakly electrophilic chloromethyliminium salt, now known as a Vilsmeier reagent. These salts can be isolated before introduction of a nucleophile and have been found to react well with electron-rich aromatic and heteroaromatic compounds,10 as well as certain types of alkenes.lb The initially formed iminium intermediate is usually hydrolyzed to produce an aldehyde. In modern synthesis applications, the most common reagents used for the formation of Vilsmeier reagents are DMF and POCI3. R1 ,.Ν^Η

R2

T

O

COCI 2

■

Rf© EDG-

N-R 1 H

R1 ©N 2 N

R ' T ci

H H

Θ Π Cl

EDG-

a Vilsmeier reagent (isolable) H,0

EDG-

V %

Much of the research on Vilsmeier reactions in the past 50 years has focused on expanding the scope of this transformation. Whereas the reaction was once limited to electron-rich aromatics and heteroaromatics, aliphatic substrates have increasingly been found to react with Vilsmeier reagents. Furthermore, alternate transformations of the iminium intermediate to form products with functional groups other than aldehyde have been developed. Finally, access to a diverse range of heterocycles is now possible due to discovery of substrate classes that are capable of undergoing intramolecular annulation reactions on the iminium intermediate.

Name Reactions for Carbocyclic Ring Formations

700

6.5.3 Mechanism When DMF is treated with carbonyl chloride, a sequence of two simple addition-elimination reactions takes place to yield a Vilsmeier reagent.

..Θ H3C

H3C

e r -ci

H3C / · .

(i/^ci CI U l

H3C

CI

H3C

^Ν.

-CI

©,Ν.

οΧ^ο

Η

ci

ci

_ u

When DMF is treated with POCI3, a more complex equilibrium mixture of iminium salts of varying electrophilicities is produced. A similar sequence of addition-elimination reactions initially takes place to yield iminium salts 1 and 2, which can react further with DMF to produce 3 and 4.5 Although each salt below is capable of undergoing a subsequent acylation reaction, salt 2 is generally considered to be the active Vilsmeier reagent. H3C

1

M^M

H 3 C"'-Y o

D n

~,

P0CI

3

H3C

(7\ 1

©N

H

CI

— = * H3C^ Y N o.p^o ci 1 er

Θ

H3C

Θ

Ω Ι

ON,

H3C"

H

OPOCIQ 2

Y ci

/ D M F \ H3C

Q|

0

3

Y N -CH 3 CI

H3C

Q|

4

Upon introduction of an aromatic nucleophile, an electrophilic aromatic substitution takes place to yield an intermediate iminium ion (5), often with good regioselectivity in favor of the isomer with less steric strain.6

Chapter 6 Transformations of C'arbocycles

701

5 then undergoes a final addition-elimination reaction with a nucleophile, usually water, to yield the product aldehyde (6). Aqueous workup conditions vary considerably but are usually basic. Whenever an imine is hydrolyzed in the following examples, water will be listed as the reagent in a separate step.

^^-{y^K

H3C„©.CH

HaC :NI-CH 3

e.® - è€>KCI :ciej

H

(H3C)2N

(H3C)2N

39©

N

// \w ~ C H 3 Ü *

(H3C)2N

6.5.4 Variations, Improvements, and Modifications The Vilsmeier reaction is used to this day in largely the same way as it was originally conceived, though its substrate scope continues to expand. One important variation, known as the Bischler-Napieralski isoquinoline synthesis, involves an intramolecular Fiedel-Crafts acylation reaction where the acylating agent resembles a Vilsmeier electrophile. If the acylated phenethylamine substrate contains an a-hydroxyl group, a subsequent dehydration yields an isoquinoline.7 POCI3

T O OH HN..R

POCI3

T O

Each component of the standard Vilsmeier conditions can be modified to increase the variety of products that may be generated within this

Name Reactions for Carbocyclic Ring Formations

702

reaction manifold. Acetylation is the most common variant, which requires the use of dimethylacetamide (DMA) in place of DMF (7—>8).8 Though less common, more sophisticated acylations can be achieved with this methodology (9—>10).9 Furthermore, when the initially formed iminium salt is sufficiently stable, it can be isolated without hydrolysis (11—>12) 10 1)DMA, POCI 3 2)H20

BnO H

O BnO

71% -OEtgNCCKChyaCOzEt, POCI3 2)H20

v-cm

86%

DMF, POCI3

HaC

H3C

83% 11

The intermediate iminium salts can also be transformed into functional groups other than carbonyls. Three common variants are quenching with hydrogen sulfide to yields thioaldehydes (13—>14),n oxime formation with hydroxylamine followed by dehydration to yield nitriles (15—>16),12 and hydride reduction to yield dialkylamines (17—>18).13

Chapter 6 Transformations of Carbocycles

co 13

N CH3

15

CH,

703

1)DMF, POCI3 2)H 2 S __| 89% 1)DMF, (COCI)2 2) NH2OH«HCI, Δ « 67%

0CH

1)DMF, POCI3 H 3 C . 3 2) NaBH4 N CH3 76%

ocm

Finally, the extension of the Vilsmeier reaction to nonaromatic substrates has greatly expanded its scope. Most aliphatic alkenes are unreactive toward Vilsmeier reagents, which are only modestly electrophilic. Accordingly, alkenes bearing π-donating substituents show increased reactivity, but only a limited set of functional groups generate simple formylated products. For example, enol ethers are formylated to yield ßketoaldehydes (19—>20),14 styrenes yield cinnamaldehydes (21—>22),15 and conjugated dienes, often formed in situ from the dehydration of allylic alcohols, yield conjugated dienals (23—»24).16

Name Reactions for Carbocyclic Ring Formations

704

H3C H3C CH 3

| H

-CH 3 'OAc

H | H

1)DMF, POCI3 2)H20 * 75%

19 H S C.

1)DMF, POCI3 2)H20 48%

»

21 H3C

CH3

1)DMF, POCI3 2)H20 92%

»

However, the reactions of most non-aromatic π nucleophiles with Vilsmeier reagents yield more complicated products. lb The reaction of the following ketone, via its enol tautomer, is illustrative. 17 1)DMF, POCI3 2)H20

X

5

80%

Θ N(CH 3 ) 2

OH

Θ

N(CH 3 ) 2

CI

Θ

N(CH3)2

H

CI

6.5.5

Θ

Synthetic Utility

This section describes prototypical reactions of Vilsmeier salts with electronrich aromatic rings, an area where the Vilsmeier reaction has proven particularly valuable. Reactions are grouped into three categories: formylation of common heteroaromatic compounds with a focus on regioselectivity, tandem formylation-cyclization sequences that annulate

Chapter 6 Transformations of Carbocycles

705

aromatic compounds, and applications of Vilsmeier reactions in natural product synthesis. Formylation of common heteroaromatic compounds On treatment with Vilsmeier salts, N-alkylpyrroles formylate in the expected 2-position unless the alkyl group is bulky, in which case formylation at the 3position is preferred.18 The 2-substituted pyrroles tend to formylate at the 5position, and 3-substituted pyrroles formylate at the 2- and 5-position with low regioselectivity. r—/~H

0= ™? - ex.« o 1)DMF, POCI 3

N R

N R

R = CH 3 R = t-Bu

Y O

N R

95% 5%

0% 64%

Furans give similar regioselectivities; however, contrasteric regioselectivity is observed in the formylation of 3-methylfuran.19 /CH3

f L o

1)DMF, POCI3

2)H20

f t

/CH3

o

75%

,H

\\ o

K

IT o

/Ti

PH3

0

8%

Indoles formylate in the 3-position,20 but indoles already substituted at the 3-position results in predominantly 7V-formylation with a lesser amount of 2-formylation. ' Benzofurmans fomylate selectively at the 2-position.22

Name Reactions for Carbocyclic Ring Formations

706

\ N H CH a \

1)DMF, POCI3 2)H20 ^97%

i

CH 3

CH 3

1)DMF, POCI3 2)H20

N 71%

\

1)DMF, POCI3 2)H20 ». 62%

H

^

N H

>*0

V

H

23% ,0

Formylation-cyclization sequences that annulate heteroaromatic compounds The Bishler-Napieralski reaction, described above, is a named reaction in which Vilsmeier formylation results in a molecule that can participate in a subsequent cyclization reaction, resulting in a net annulation. There are numerous other examples of similar tandem sequences, most of which are not named reactions, and they generally give only modest yields. e For instance, when ketone 25 is treated with a Vilsmeier reagent, isoflavone 26 is produced in nearly quantitative yield. O Ph POCI3 25

HO

© CHa

OH N CH 3

99%

Ph

HO

O 26

Benzothiophenes can be prepared from the corresponding phenyl ethers in a similar manner. In this case, the yield increased drastically when a more electron-donating amine substituent was present on the substrate.24

707

Chapter 6 Transformations of Carbocycles

H 3 C.©.CH 3 DMF POCI3

Ph

O

Ph

R O

\> O

R = OCH3 , 25% R = NEt2 , 7 8 %

Ü Ph

Pyrimidine derivatives also are formylated under Vilsmeier conditions. In the following example, a phenyl susbtituent is ideally placed for a subsequent annulation. 5 O

DMF POCI3 Ph

96%

CH,

" "N'

Y

CH 3

Applications of Vilsmeier reactions in natural product synthesis A standard Vilsmeier formylation was used as the final step in a synthesis of homofascaplysin C (28).26 ^5v-\

1)DMF, POCI3 2)Η20

Ν-γ'^ι

88% 27

Vilsmeier formylation of enol ether 29 was an early step in the preparation of illudin C.27 In this case, a concomitant bromination also took place to form 30. 1)DMF, POCI3

CH3 2)H 2 0 TESO

CH, 29

—

64%

"

H

Jl Br

iTV',CH3

MGH3

n

30

.

YVv C H 3

V yr H3C OH

rac-illudin C

un

3

708

Name Reactions for Carbocyclic Ring Formations

Finally, an adaptation of Vilsmeier conditions was used successfully in a synthesis of tashiromine. In this case, the amide was activated by triflic 28 anhydride. OTBDMS

Tf 2 0 2,6-di-tert-butyl4-methylpyridine

[R]

93% rac-tashiromine

6.5.6

Experimental

Compound 28 26

27

Phosphorus oxychloride (0.2 mL, 2.2 mmol) was added slowly via syringe to ice-cold, dry DMF (5 mL). The resulting solution, protected from moisture with a drying tube, was stirred for 15 min at room temperature and then recooled. A solution of 27 (0.53 g, 2.0 mmol) in DMF (10 mL) was then added over 2 min, and the solution was then stirred at room temperature for 3 h and poured into ice water (50 mL). The yellow mixture was made alkaline with 2 M sodium hydroxide, and the resulting precipitate was collected by filtration, washed thoroughly with water, and dried (50 °C, ~1 torr) to give 28 (0.50 g, 88%) as a yellow solid. Compound 30

27

,CH3 TESO

CH 3

29

H

- V; Br

CH 3 CH 3

30

To a solution of DMF (513 mL, 6.63 mmol) in methylene chloride (10 mL) was added phosphorus oxybromide (1.58 g, 5.52 mmol), and the resulting solution was stirred at room temperature for 1 hr as a white precipitate formed. A solution of 29 (500 mg, 2.21 mmol) in methylene chloride (2 mL) was added to the mixture, and the resultant slurry was stirred at room

Chapter 6 Transformations of Carbocycles

709

temperature for 72 h and poured onto ice (5 g). The solution was neutralized with sodium bicarbonate and extracted with hexane/ether (9:1). The combined organic layers were washed with saturated aqueous sodium bicarbonate, dried over sodium sulfate, and concentrated. Purification by silica get chromatography (ethyl acetate/hexane, 3:97, silica gel deactivated with 10% triethylamine) gave exclusively one regioisomer as a colorless oil (289 mg, 64%). 6.5.7 References 1.

2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18. 19. 20. 21. 22. 23. 24. 25. 26. 27. 28.

[R] (a) Perumal, P. T. Indian J. Heterocycl. Chem. 2001 11, 1-8. (b) Jones, G.; Stanforth, S. P. Org. React. 2000, 56, 355-659. (c) Jones, G.; Stanforth, S. P. Org. React. 1997, 49, 1-330. (d) Meth-Cohn, O.; Stanforth, S. P. Comp. Org. Syn. Vol. 2, Trost, B. M.; Fleming, I., eds. Pergamon Press, Oxford, 1991, pp. 777-794. (e) MethCohn, O.; Tarnowski, B. Adv. Heterocycl. Chem. 1982, 31, 207-236. (f) Jutz, C. Adv. Org. Chem. 1976, 9, 225-342. (g) Seshadri, S. J. Set. Ind. Res. 1973, 32, 128-149. (h) Burn, D. Chem. Ind. 1973, 870-873. Dimroth, O.; Zoeppritz, R. Ber. Dtsch. Chem. Ges. 1902, 35, 995-996. Fischer, O.; Müller, A.; Vilsmeier, A. J. Prakt. Chem. 1925, 69-87. Vilsmeier, A.; Haack, A. Ber. 1927, 60B, 119-122. Martin, G. J.; Poignant, S. J. Chem. Soc., Perkin Trans. 2 1974, 642-646. Downie, I. M.; Earle, M. J.; Heaney, H.; Shuhaibar, K. F. Tetrahedron 1993, 49, 40154034. [R] Whaley, W. M.; Govindachari, T. R. Org. React. 1951, 6, 74-150. Anthony, W. C. J. Org. Chem. 1960, 25, 2049-2053. Anderson, Jr. A. G.; Breazeale, R. D. J. Org. Chem. 1969, 34, 2375-2384. Hafner, K.; Schneider, J. Justus Liebigs Ann. Chem. 1959, 624, ll-W. McKenzie, S.; Molloy, B. B.; Reid, D. H. J. Chem. Soc. C1966, 1908-1913. Barnett, G. H.; Anderson, H. J.; Loader, C. E. Can. J. Chem. 1980, 58, 409^411. Shawcross, A. P.; Stanforth, S. P. Tetrahedron 1989, 45,7063-7076. Popper, T. L.; Faro, H. P.; Carlon, F. E.; Herzog, H. L. J. Med. Chem. 1972, 75, 555556. Witiak, D. T.; Williams, D. R.; Kakodkar, S. V.; Hite, G.; Shen, M.-S. J. Org. Chem. 1974,39, 1242-1247. Reddy, M. P.; Rao, G. S. K. Ind. J. Chem., Sec. B 1982, 2IB, 757-758. Paquette, L. A.; Johnson, B. A.; Hinga, F. M. Org. Synth. 1966, 46, 18-20. Jones, R. A.; Candy, C. F.; Wright, P. H. J. Chem. Soc, C. 1970, 2563-2567. Chadwick, D. J.; Chambers, J.; Hargraves, H. E.; Meakins, G. D.; Snowden, R. L. J. Chem. Soc. Perkin Trans. 1 1973,2327-2332. Klohr, S. E.; Cassady, J. M. Synth. Commun. 1988,18, 671-674. Chatterjee, A.; Biswas, K. M. J. Org. Chem. 1973, 38,4002^004. Suu, V. T.; Buu-Hoi, N. P.; Xuong, N. D. Bull. Soc. Chim. Fr. 1962, 1875-1877. Kagal, S. A.; Nair, P. M.; Ventkataraman, K. Tetraheron Lett. 1962, 593-597. Hirota, T.; Fujita, H.; Sasaki, K.; Namba, T.; Hayakawa, S. Heterocycles 1986, 24, 771776. Yoneda, F.; Mori, K.; Ono, M.; Kadokawa, Y.; Nagao, E.; Yamaguchi, H. Chem. Pharm. Bull. 1980,25,3514-3520. Gribble, G. W.; Pelcman, B. J. Org. Chem. 1992, 57, 3636-3642. Aungst, Jr., R. A.; Chan, C; Funk, R. L. Org. Lett. 2001, 3, 2611-2613. Bélanger, G.; Larouche-Gauthier, R.; Ménard, F.; Nantel, M.; Barabé, F. J. Org. Chem. 2006, 71, 704-712.

710

6.6

Name Reactions for Carbocyclic Ring Formations

von Richter Reaction

Martin E. Hayes 6.6.1

Description

^ . N0 2 ^ 1

KCN, H20 / R'OH 80-200 °C R

2

The von Richter reaction is the nucleophüic aromatic substitution of a nitroarene (1) with potassium cyanide to give the c/«e-substituted benzoic acid (2). The reaction is characterized by the observed regiochemistry of the product where the carboxyl group occupies a position ortho to the nitro group that is lost. 6.6.2

Historical Perspective

Victor von Richter was a German chemist1 whose support of Mendeleev's theory of periodicity,2 later formalized into the modern Periodic Table of the Elements, played an important role in its adoption throughout western Europe. He was widely regarded for his textbooks on organic and inorganic chemistry4 that were used throughout Europe and the United States at the turn of the 20th century. Among his research accomplishments is the first synthesis of racemic BINOL5 and the first synthesis of chinoline.6 The von Richter reaction, also known as the von Richter rearrangement, was first disclosed in 18717"9 and the results were revised10 in 1875 to reflect the correct regiochemistry of the benzoic acid products. The reaction was largely ignored until the mid-20( century1'when it was further examined in a series of critical experiments that lead to a fuller understanding of the scope and ultimate elucidation of the mechanism. The reaction has been of limited synthetic value due to the low isolated yield of the products. 6.6.3

Mechanism

The mechanism of the von Richter reaction was a subject of active investigation during the mid-20th century and accounts of the debate surrounding it have been detailed previously.1 The reaction is a classic

Chapter 6 Transformations of Carbocycles

711

example of an aromatic cz'ne-substitution.13 and one of only a handful of such reactions that do not proceed via the intermediacy of an aryne.14 The 15-K mechanism has been probed through a series of critical studies 16 using 18N 2 15 labeled ammonia and substrate H-labeled solvent and substrate, and 0labeled water-17 along with careful analysis of the reaction byproducts. Θ

Θ

°T8'° KCN

-HΘ

H

8i rV

N

NH2

6 HO) n H N-N

11

12

13

The currently accepted mechanism involves the addition of cyanide ortho- to the nitro group to give intermediate 5. The nitrile is then subject to intramolecular attack to generate the bicyclic intermediate 6. Previous 18

mechanistic hypotheses have invoked this same intermediate (6), yet its fate was a matter of contention until 1960 when Rosenblum,15 in a series of elegant 15N-labeling experiments coupled with careful interpretation of

712

Name Reactions for Carbocyclic Ring Formations

existing results, proposed that the heterocyclic ring ionizes to give an aryl nitroso amide (7). This nitroso intermediate was independently synthesized and demonstrated to provide the observed product when exposed to the von Richter reaction conditions.19 NH2 O

CH3C(0)OOH NaOAc, EtOH

NH,

85%

^v *N

14

KCN 50% EtOH (aq) »140-150°C 20%

OH

16

15

HN'NH

Pb(OAc)4, MgO

KCN, EtOH

MeCN,-10°C

80%

►

(

18

17

/

16

Intermediate 7 is then proposed to undergo recombination of the nitroso and ortho-amide groups to form an indazolonone 9. The unstable indazolonone then decomposes to nitrogen gas and the c/'«e-substituted benzoic acid (13) via the benzoylnitrile (11). The proposed indazolonone intermediate has also been independently prepared and shown to readily decompose to the observed benzoic acid product.20 Alternative proposed intermediates, such as a benzonitrile 20, have been observed to hydrolyze at a rate that is demonstrably slower than the overall reaction rate, conclusively eliminating it as a competent intermediate. Λ 1

CI

CI

CN

N0 2 19

KCN 48% EtOH(aq)> CI 150°C

20

KCN 48% EtOH(aq)

CI NO, 19

OH

150°C 21 31%

no Benzamide observed

Chapter 6 Transformations of Carbocycles

713

6.6.4 Variations and Improvements The scope of the von Richter reaction has been examined with respect to substituent effects where the sum of the arene field effects plays an important role in determining optimal conversion to the product. Bunnett18 reported in 1956 that appreciable conversion was observed only with substituents having summed sigma values, excluding the nitro group, between -0.2 and 0.6 where optimal conversion occurs with sigma values between 0.2 and 0.5. The reaction is inhibited by substituents ortho- to the nitro group which prevent efficient orbital overlap of the pi-system due to steric interactions. .NO

KCN, 48% EtOH(aq) reflux 37%

Br 23

24

NO,

KCN, 48% EtOH(aq) reflux

Br

2% (44% recovered SM)

25

Reactions of di-nitro compounds typically do not proceed via the von Richter pathway but rather give products of /pso-substitution at one of the nitro centers. Similarly, activated heterocycles such as 6-nitroquinoline, are reported to proceed via /pso-substitution instead of the von Richter pathway.22 0

2Ν\ζ^^/Ν02 if η 26

KCN, MeOH reflux 27

Many examples of the von Richter reaction have been conducted in sealed reaction vessels, however, a more convenient method involves refluxing the reaction mixture, a modification that has been shown to give comparable yields.16 The reaction proceeds optimally in aqueous alcohol

714

Name Reactions for Carbocyclic Ring Formations

solvents including aqueous mixtures of 48-95% methanol, ethanol, 2ethoxyethanol, or ethylene glycol. The latter solvents have been employed, owing to their higher boiling points, while the standard reaction medium is 48%> aqueous ethanol.22 Limited examples of other solvents have been disclosed, most notably the use of DMSO has been reported to give several byproducts not previously disclosed.23 6.6.5 Synthetic Utility The synthetic utility of the von Richter reaction has been limited due to the low isolated yields of the benzoic acid products. The reported yields starting from nitroarenes range from 0.5-50%, though in some cases unreacted starting material can also be recovered.22 The low overall conversion is believed to be due, at least in part, to competing hydrolysis of the cyanide reagent in the reaction medium and often improved conversion is observed with greater excess of cyanide salts.16 Published examples of the von Richter reaction have been limited to nitrobenzene and nitronapthalene derivatives. In the case of 2nitronapthalene, treatment with potassium cyanide in refluxing 48% ethanol for 4 h provides a 13% yield of 1-carboxynapthalene.18 KCN, 48% EtOH(aq) reflux

13%

Recently, a variation of the von Richter reaction was disclosed involving TV-arylnitrones as surrogate nitroarenes that also are proposed to undergo a c/'«e-substitution reaction with potassium cyanide.24 The reaction with potassium cyanide in refluxing 33% ethanol for 2 h provides a 52% yield of benzoic acid and is one of the highest yielding examples of a von Richter reaction. O

KCN, 33% EtOH(aq) reflux 52%

Chapter 6 Transformations of Carbocycles

6.6.6

715

Experimental

Preparation of 3-Chlorobenzoic Acid (21)22 CI

KCN, 48% EtOH(aq) N0 2 19

40%

*21

A flask was charged with 4-chloronitrobenzene (3.0 g, 0.019 mol) and KCN (6.45 g, 0.099 mol) in 26 mL of 48% aqueous ethanol, and the reaction mixture was refluxed for 48h. The mixture was allowed to cool to rt and transferred into a flask with the aid of water, then the solution was made basic with the addition of NaOH. Organic solvent and unreacted starting material were removed by steam distillation and then the residue was acidified. Steam was again passed through the acidified solution until 1.5 L of distillate was collected. The pH of the distillate was adjusted with NaHC03, and the volume of the solution was reduced via distillation to approximately 200 mL. Then the residue was acidified. The resulting precipitate was collected by filtration to give 1.2 g (0.0076 mol) 3chlorobenzoic acid. 6.6.7

References

1. 2. 3.

Pransnitz, G. Chem. Ber. 1891, 24, 1123-1130. Kaji, M. Foundations of Chemistry. 2003, 5, 189-214. v. Richter, V. Smith, E., Ed. Victor von Richters Organic Chemistry, 2 ed. Blakiston, Philadelphia, 1900. v. Richter, V. Klinger, H.; Smith, E., Ed. Victor von Richter's Textbook of Inorganic Chemistry, 5 ed. P. Blakiston, Philadelphia, 1900. Brunei, J. Chem. Rev. 2005, 105, 857-989. v. Richter, V. Chem. Ber. 1883, 16, 677-683. v. Richter, V. Chem. Ber. 1871, 4, 21-22. v. Richter, V. Chem. Ber. 1871, 4,459^168. v. Richter, V. Chem. Ber. 1871, 4, 553-555. v. Richter, V. Chem. Ber. 1875, 8, 1418-1425. [R] Huisgen, J. S. Angew. Chem. 1960, 72, 294-315. [R] Shine, H. Shine, H. J. ed. Aromatic Rearrangements, Elsevier, New York, 1967, pp. 326335. [R] Suwinski, J. S.; Swierczek, K. Tetrahedron 2001, 57, 1639-1662. [R] Bunnett, J. Q. Rev. Chem. Soc. 1958, 122, 1-16. Rosenblum, M. J. Am. Chem. Soc. 1960, 82, 3796-3798. Bunnett, J. F.; Rauhut, M. M.; Knutson, D.; Bussell, G. E. J. Am. Chem. Soc. 1954, 76, 5755-5761. Samuel, O.J. Chem. Soc. 1960, 1318-1320. Bunnett, J. F.; Rauhut, M. M. J. Org. Chem. 1956, 21, 934-938.

4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18.

Name Reactions for Carbocyclic Ring Formations Ibne-Rasa, K. M.; Koubek, E. J. Org. Chem. 1963, 28, 3240-3241. Ullman, E.; Bartkus, E. Chem. Ind.1962, 93-94. Bunnett, J. F.; Rauhut, M. M. J. Org. Chem. 1956, 21, 944-948. Bunnett, J. F.; Cormack, J. F.; McKay, F. C. J. Org. Chem. 1950, 75,481-190. Rogers, G. T.; Ulbricht, T. L. V. Tetrahedron Lett. 1968, P, 1029-1032.

Name Reactions for CarbocycUc Ring Formations Edited by Jie Jack Li Copynght © 2010 John Wiley & Sons, Inc.

Appendixes Appendix 1 Table of Contents for Volume 1: Name Reactions in Heterocyclic Chemistry Published in 2005 PART 1

THREE- AND FOUR-MEMBERED HETEROCYCLES

1

Chapter 1 Epoxides and Aziridines 1.1 Corey-Chaykovsky reaction 1.2 Darzens glycidic ester condensation 1.3 Hoch-Campbell aziridine synthesis 1.4 Jacobsen-Katsuki epoxidation 1.5 Paterno-Büchi reaction 1.6 Sharpless-Katsuki epoxidation 1.7 Wenker aziridine synthesis

1 2 15 22 29 44 50 63

PART 2

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FIVE-MEMBERED HETEROCYCLES

Chapter 2 Pyrroles and Pyrrolidines 2.1 Barton-Zard reaction 2.2 Knorr and Paal-Knorr pyrrole syntheses 2.3 Hofmann-Löffler-Freytag reaction

69 70 79 90

Chapter 3 Indoles 3.1 Bartoli indole synthesis 3.2 Batcho-Leimgruber indole synthesis 3.3 Bucherer carbazole synthesis 3.4 Fischer indole synthesis 3.5 Gassman indole synthesis 3.6 Graebe-Ullman carbazole synthesis 3.7 Hegedus indole synthesis 3.8 Madelung indole synthesis 3.9 Nenitzescu indole synthesis 3.10 Reissert indole synthesis

99 100 104 110 116 128 132 135 140 145 154

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Chapter 4 Furans 4.1 Feist-Bénary furan synthesis 4.2 Paal-Knorr furan synthesis

160 168

Chapter 5 Thiophenes 5.1 Fiesselmann thiophene synthesis 5.2 Gewald aminothiophene synthesis 5.3 Hinsberg synthesis of thiophene derivatives 5.4 Paal thiophene synthesis

183 184 193 199 207

Chapter 6 Oxazoles and Isoxazoles 6.1 Claisen isoxazole synthesis 6.2 Cornforth rearrangement 6.3 Erlenmeyer-Plöchl azlactone synthesis 6.4 Fischer oxazole synthesis 6.5 Meyers oxazoline method 6.6 Robinson-Gabriel synthesis 6.7 van Leusen oxazole synthesis

219 220 225 229 234 237 249 254

Chapter 7 Other Five-Membered Heterocycles 7.1 Auwers flavone synthesis 7.2 Bucherer-Bergs reaction 7.3 Cook-Heilbron 5-amino-thiazole synthesis 7.4 Hurd-Mori 1,2,3-thiadiazole synthesis 7.5 Knorr pyrazole synthesis

261 262 266 275 284 392

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Chapter 8 8.1 8.1.1 8.1.1.1 8.1.1.2 8.1.1.3 8.1.1.4 8.1.1.4.1 8.1.1.4.2 8.1.1.4.3 8.1.1.4.4

Pyridines Preparation via condensation reactions Hantzsch (dihydro)-pyridine synthesis Description Historical perspective Mechanism Variations Guareschi-Thorpe pyridine synthesis Chichibabin (Tschitschibabin) pyridine synthesis Bohlmann-Rahtz pyridine synthesis Kröhnke pyridine synthesis

302 303 304 304 3 04 305 307 307 308 309 311

Appendixes

8.1.1.4.5 8.1.1.5 8.1.1.6 8.1.1.6.1 8.1.1.6.2 8.1.1.7 8.2 8.2.1 8.3 8.3.1 8.3.2 8.4

Petrenko-Kritschenko piperidone synthesis Improvements or modifications Experimental Three-component coupling Two-component coupling References Preparation via cycloaddition reactions Boger reaction Preparation via rearrangement reactions Boekelheide reaction Ciamician-Dennstedt rearrangement Zincke reaction

719

313 314 320 320 320 321 323 323 340 340 350 355

Chapter 9 Quinolines and Isoquinolines 9.1 Bischler-Napieralski reaction 9.2 Camps quinoline synthesis 9.3 Combes quinoline synthesis 9.4 Conrad-Limpach reaction 9.5 Doebner quinoline synthesis 9.6 Friedländer synthesis 9.7 Gabriel-Colman rearrangement 9.8 Gould-Jacobs reaction 9.9 Knorr quinoline synthesis 9.10 Meth-Cohn quinoline synthesis 9.11 Pfitzinger quinoline synthesis 9.12 Pictet-Gams isoquinoline synthesis 9.13 Pictet-Hubert reaction 9.14 Pictet-Spengler isoquinoline synthesis 9.15 Pomeranz-Fritsch reaction 9.16 Riehm quinoline synthesis 9.17 Skraup/Doebner-von Miller reaction

375 376 386 390 398 407 411 416 423 437 443 451 457 465 469 480 487 488

Chapter 10 Other Six-Membered Heterocycles 10.1 Algar-Flynn-Oyamada reaction 10.2 Beirut reaction 10.3 Biginelli reaction 10.4 Kostanecki-Robinson reaction 10.5 Pinner pyrimidine synthesis 10.6 von Richter cinnoline reaction

495 496 504 509 521 536 540

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vii viii ix

Chapter 1 Asymmetric Synthesis 1.1 CBS reduction 1.2 Davis chiral oxaziridine reagents 1.3 Midland reduction 1.4 Noyori catalytic asymmetric hydrogenation 1.5 Sharpless asymmetric hydroxylation reactions

1 2 22 40 46 67

Chapter 2 Reduction 2.1 Eschweiler-Clark reductive alkylation of amines 2.2 Gribble reduction of diaryl ketones 2.3 Luche reduction 2.4 Meerwein-Ponndorf-Verley reduction 2.5 Staudinger reaction 2.6 Wharton reaction

85 86 93 112 123 129 152

Chapter 3 Oxidation 3.1 Baeyer-Villiger oxidation 3.2 Brown hydroboration reaction 3.3 Burgess dehydrating reagent 3.4 Corey-Kim oxidation 3.5 Dess-Martin periodinane oxidation 3.6 Tamao-Kumada-Fleming oxidation 3.7 Martin ' s sulfurane dehydrating reagent 3.8 Oppenauer oxidation 3.9 Prilezhaev reaction 3.10 Rubottom oxidation 3.11 Swern oxidation 3.12 Wacker-Tsuji oxidation 3.13 Woodward cz's-dihydroxylation

159 160 183 189 207 218 237 248 265 274 282 291 309 327

Chapter 4 Olefination 4.1 Chugaev elimination 4.2 Cope elimination reaction 4.3 Corey-Winter olefin synthesis

333 334 343 354

Appendixes

4.4 4.5 4.6 4.7 4.8

Perkin reaction (cinnamic acid synthesis) Perkow vinyl phosphate synthesis Ramberg-Bäcklund olefìn synthesis Shapiro reaction Zaitsev elimination

721

363 369 386 405 414

Chapter 5 Amine Synthesis 5.1 Fukuyama amine synthesis 5.2 Gabriel synthesis 5.3 Leuckart-Wallach reaction

423 424 438 451

Chapter 6 Carboxylic Acid Derivatives Synthesis 6.1 Fischer-Speier esterification 6.2 Mukaiyama esterification 6.3 Ritter reaction 6.4 Strecker amino acid synthesis 6.5 Yamada coupling reagent 6.6 Yamaguchi esterification

457 458 462 471 477 500 545

Chapter 7 Miscellaneous Functional Group Manipulations 7.1 Balz-Schiemann reaction 7.2 Buchwald-Hartwig reactions 7.3 Haloform reaction 7.4 Hunsdiecker reaction 7.5 Japp-Klingemann hydrazone synthesis 7.6 Krapcho decarboxylation 7.7. Nef reaction 7.8 Prins reaction 7.9 Regitz diazo synthesis 7.10 Sommelet reaction

551 552 564 610 623 630 635 645 653 658 689

Appendixes Appendix 1. Table of Contents for Volume 1: Name Reactions in Heterocyclic Chemistry Appendix 2. Table of Contents for Volume 3: Name Reactions for Chain Extension Appendix 3. Table of Contents for Volume 4: Name Reactions for Ring Formation Appendix.4 Table of Contents for Volume 5 Name Reactions in Heterocyclic Chemistry-2 Subject Index

697 697 700 703 705 709

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VI

vii viii

Chapter 1.

Organometallics

1

Section 1.1 1.1.1 1.1.2 1.1.3 1.1.4 1.1.5 1.1.6 1.1.7 1.1.8

Palladium Chemistry Heck reaction Hiyama cross-coupling reaction Kumada cross-coupling reaction Negishi cross-coupling reaction Sonogashira reaction Stille coupling Suzuki coupling Tsuji-Trost reaction

2 2 33 47 70 100 133 163 185

Section 1.2 1.2.1 1.2.2 1.2.3

Organocopper Reagents Castro-Stephens coupling Glaser coupling Ullmann reaction

212 212 236 258

Section 1.3 1.3.1 1.3.2 1.3.3 1.3.4

Other Organometallic Reagents McMurry coupling Nicholas reaction Nozaki-Hiyama-Kishi reaction Tebbe olefination

268 268 284 299 319

Chapter 2.

Carbon-Chain Homologations

335

2.1 2.2 2.3 2.4 2.5 2.6 2.7 2.8 2.9

Arndt-Eistert homologation Morita-Baylis-Hillman reaction Benzoin condensation Corey-Fuchs reaction Henry reaction Horner-Wadsworth-Emmons reaction Julia-Lythgoe olefination Knoevenagel condensation Mukaiyama aldol reaction

336 350 381 393 404 420 447 474 502

Appendixes

723

2.10 2.11 2.12 2.13

Peterson olefination Sakurai allylation reaction Stetter reaction Wittig reaction

521 539 576 588

Chapter 3.

Radical Chemistry

613

Barton-McCombie deoxygenation Barton nitrite photolysis Sandmeyer reaction Wohl-Ziegler reaction

614 633 648 661

3.1 3.2 3.3 3.4

Appendixes Appendix 1, Appendix 2, Appendix 3, Appendix 4, Appendix 5, Subject index

Table of Contents for Volume 1: 675 Name Reactions in Heterocyclic Chemistry Table of Contents for Volume 2: 678 Name Reactions for Functional Group Transformations Table of Contents for Volume 4: 680 Name Reactions for Homologations-2 Table of Contents for Volume 5: 682 Name Reactions for Carbocyclic Ring Formations Table of Contents for Volume 6: 684 Name Reactions in Heterocyclic Chemistry-II 687

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Appendix 4 Table of Contents for Volume 3: Name Reactions for Homologations-Part II Published in 2009 Foreword Preface Contributing Authors

vi vii viii

Chapter 1. Rearrangements

1

Section 1.1 1.1.1 1.1.2 1.1.3 1.1.4 1.1.5 1.1.6 1.1.7 1.1.8 1.1.9 1.1.10

Concerted rearrangement Alder ene reaction Claisen and related rearrangements Cope and related rearrangements Curtius rearrangement Hofmann rearrangement Lossen rearrangement Overman rearrangement [1,2]-Wittig rearrangement [2,3]-Wittig rearrangement Wolff rearrangement

2 2 33 88 136 164 200 210 226 241 257

Section 1.2 1.2.1 1.2.2 1.2.3 1.2.4 1.2.5 1.2.6 1.2.7

Cationic rearrangement Beckmann rearrangement Demjanov rearrangement Meyer-Schuster rearrangement Pinacol rearrangement Pummerer rearrangement Schmidt rearrangement Wagner-Meerwein rearrangement

274 274 293 305 319 334 353 373

Section 1.3 1.3.1 1.3.2 1.3.3 1.3.4 1.3.5 1.3.6 1.3.7 1.3.8

Anionic rearrangement Benzilic acid rearrangement Brook rearrangement Favorskii rearrangement Grob fragmentation Neber rearrangement Payne rearrangement Smiles rearrangement Stevens rearrangement

395 395 406 438 452 464 474 489 516

Appendixes

725

Chapter 2.

Asymmetrie C-C bond formation

531

2.1 2.2 2.3 2.4

Evans aldol reaction Hajos-Wiechert reaction Keck stereoselective allylation Roush allylboronation

532 554 583 613

Chapter 3.

Miscellaneous homologation reactions

641

3.1 3.2 3.3 3.4 3.5 3.6

Bamford-Stevens reaction Mannich reaction Mitsunobu reaction Parham cyclization Passerini reaction Ugi reaction

642 653 671 749 765 786

Appendixes Appendix 1, Appendix 2, Appendix 3, Appendix 4, Appendix 5, Subject index

Table of Contents for Volume 1: 807 Name Reactions in Heterocyclic Chemistry Table of Contents for Volume 2: 810 Name Reactions for Functional Group Transformations Table of Contents for Volume 3: 812 Name Reactions for Homologations-I Table of Contents for Volume 5: 814 Name Reactions for Ring Formations Table of Contents for Volume 6: 816 Name Reactions in Heterocyclic Chemistry-II 819

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Appendix 5 Table of Contents for Volume 6: Name Reactions in Heterocyclic Chemistry-II Due in 2011 PART 1

THREE- AND FOUR-MEMBERED HETEROCYCLES

Chapter 1 Aziridines and Epoxides 1.1 Blum aziridine synthesis 1.2 Gabriel-Heine aziridine isomerization 1.3 Graham diziririne synthesis 1.4 Hassner aziridine synthesis 1.5 Scheiner aziridine synthesis 1.6 Shi epoxidation PART 2

FIVE-MEMBERED HETEROCYCLES

Chapter 2 Pyrroles and Pyrrolidines 2.1 Clauson-Kass pyrrole synthesis 2.2 Ehrlich reaction of pyrroles and indoles 2.3 Houben-Hoech acylation of pyrroles 2.4 Overman pyrrolidine synthesis 2.5 Padwa pyrroline synthesis 2.6 Trofimov synthesis of pyrroles Chapter 3 Indoles 3.1 Bischler indole synthesis 3.2 Borsche-Drechsel cyclization 3.3 Fukuyama indole synthesis 3.4 Gassman oxindole synthesis 3.5 Larock indole synthesis 3.6 Matinet dioxindole synthesis 3.7 Mori-Ban indole synthesis 3.8 Neber-Bosset oxindole synthesis 3.9 Sandmeyer diphenylurea/isonitrosoacetanilide isatin synthesis 3.10 Sommelet-Hauser rearrangement (indole) 3.11 Stollé synthesis (Hinsberg-Stollé) oxindole Chapter 4 Furans 4.1 Nierenstein reaction 4.2 Perkin rearrangement

Appendixes

4.3

Ueno-Stork radical cyclization

Chapter 5 Oxazoles and isoxazoles 5.1 Davidson oxazole synthesis 5.2 Fischer oxazole synthesis 5.3 Japp oxazole synthesis 5.4 Robinson-Gabriel synthesis 5.5 Schöllkopf oxazole synthesis Chapter 6 Other five-membered heterocycles 6.1 Bamberger imidazole cleavage 6.2 Dimroth triazole synthesis 6.3 Finegan tetrazole synthesis 6.4 Hantsch thiazole synthesis 6.5 Huisgen tetrazole rearrangement 6.6 Knorr pyrazole synthesis 6.7 Pechmann pyrazole synthesis PART 3

SIX-MEMBERED HETEROCYCLES

Chapter 7 Pyridines 7.1 Baeyer pyridine synthesis 7.2 Katritzky reaction Chapter 8 Quinolines and Isoquinolines 8.1 Betti reaction 8.2 Bernthsen acridine/acridone synthesis 8.3 Lehmstedt-Tanasescu reaction 8.4 Niementowski quinoline synthesis 8.5 Povarov reaction Chapter 9 six-membered heterocycles 9.1 9.2 9.3 9.4 9.5 9.6 9.7 9.8 9.9

Balaban-Nenitzescu-Praill reaction Borsche cinnoline synthesis Gutknecht pyrazine synthesis Niementowski quinazoline synthesis Niementowski quinazolone synthesis Pechmann pyrone synthesis Robinson-Schöpf condensation Simonis chromone cyclization Wesseley-Moser rearrangement

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728

9.10 9.11

Widman-Stoermer cinnoline synthesis Wichterle reaction

Chapter 10 Miscellaneous reactions in heterocyclic chemistry 10.1 10.2 10.3 10.4 10.5 10.6

ANRORC mechanism Boulton-Katritzky rearrangement Chichibabin amination reaction Dimroth rearrangement Hantzsch synthesis of pyrroles, pyridines and thiazoles Ortoleva-King reaction

Appendixes Appendix 1, Appendix 2, Appendix 3, Appendix 4, Appendix 5, Subject index

Table of Contents for Volume 1 : Name Reactions in Heterocyclic Chemistry Table of Contents for Volume 2: Name Reactions for Functional Group Transformations Table of Contents for Volume 3: Name Reactions for Homologations-I Table of Contents for Volume 4: Name Reactions for Homologations-II Table of Contents for Volume 5: Name Reactions for Ring Formations

Name Reactions for CarbocycUc Ring Formations Edited by Jie Jack Li Copynght © 2010 John Wiley & Sons, Inc.

Index

Abacavir, 174 Ab initio calculations, 689-690 Absorption, 154, 315 Abyssomicin C, 299-300, 561 Acetal groups, 311 Acetaldehyde, 83, 242, 596 Acetal acid, 41 Acetals, 33, 143,447, 270. See also Acetal groups Acetamides, 29 Acetate, 534 Acetic acid, 37, 268, 688 Acetic anhydride, 122 Acetone, 469 Acetonides, 57, 61 Acetonitrile, 155-157, 165, 174, 312, 455, 580-581, 678,680-681 Acetophenones, 594 Acetoxycrenulide, 29-30 Acetoxy group, 477 Acetylation, 245, 477, 615, 702 Acetyl chloride, 60, 89 Acetylenes, 147,309,311 Acetylenic groups, 211, 219 Acetyl groups, 77 Acidification, 690 Acid(s), see types of acids functions of, 656, 661 solvolysis, 375. Acremine G, 296 Acrolein, 670 Acrylonitrile, 163-164, 582-583 Activation

barriers, 130, 257 energy, 113,279,383 Acyclic systems, 30 Acyclovir, 19 Acyl chloride, 51-52, 601 groups, 95, 600 halides, 611 migration, 148, 150-151 Acylals, 51 Acylation, 63, 105, 135, 205, 314, 345, 347, 350351, 409, 590, 611-612, 680, 682, 700. See also Alkylation; Friedel-Crafts acylation Acylimidazoles, 656, 658, 660-661 Acyliminium, 615, 640, 642-643 Acylium, 343, 610, 614 Acylphosphonates, 656-659 Acyls, 168 Acylsilane, 80 Additives Elbs reaction, 328-329 Pauson-Khand reaction, 152-153, 155, 157-158, 170, 175 Adipate, 100-101 Adsorption, 152 Aerobic conditions and reactions, 375, 692 Aflatoxin, 319, 682 Agelstatin A, 508 Alcohol(s) allenic, 7 allylic, 30, 40, 518, 525, 545, 683, 703 amine, 54 729

730

Index

Alcohol(s) (continued) amino, 102 asymmetric Friedel-Crafts reaction, 600, 602-605, 622-623, 652,654 Bardman-Sengupta phenantherene synthesis, 200, 204, 206, 208 benzyl, 86-87, 591 biaryl, 35 de Mayo reaction, 452, 459, 476 Dieckmann condensation, 94 Freund reaction, 2, 5-6 homoallylic, 17, 524 homopropargylic, 73-74 Houben-Hoesch reaction, 683 hydrobenzyl, 86 Kishner cyclopropane synthesis, 10 Kolbe-Schmitt reaction, 688 Pauson-Khand reaction, 153, 155, 160, 165, 167168 ring-closing metathesis, 506, 516, 518, 525, 531, 539, 545, 550 Robinson annulation, 387, 402 Simmons-Smith cyclopropanation, 38 Staudinger ketene cycloaddition, 63 von Richter reaction, 713 Weiss-Cook reaction, 186, 189-190 Aldehydes, 7, 18, 52-54, 56-57, 73, 82-84, 143, 172, 189-190, 286, 292, 296,424,469, 590, 600, 602, 623-624, 626, 638, 644-647, 656, 661665, 698-699 Alder endo rule, 278 Aldimines, 47-50, 287, 631, 633 Aldimino enediynes, 214 Aldols, 181-182, 186, 192-194, 313, 337, 387, 396, 405, 447, 457-458, 460, 470, 477-478 Aliphatics, 212, 424, 590, 601, 637, 639, 644-647, 703 Alkali, 336 Alkaloids, 58, 143, 163, 189, 304, 363, 511, 665, 667-668 Alkanes, 136, 140, 600, 602, 604-607 Alkenes, 24, 27, 29, 73, 82, 136, 140, 147, 149-155, 157, 160, 163, 170, 173-174, 186, 192, 200, 204, 268, 275, 291, 293, 301-302, 317, 362, 558, 562, 565, 596, 600, 604-607, 649, 703 Alkenyls, 133,203,360 Alkoxides, 15,35,38,97 Alkoxy, 56, 128, 132, 136, 362, 416, 660 Alkoxyammonium chloride, 624

Alkylating agents, 600, 602-605, 615-623 Alkyl groups blocking, 607-608 electron-releasing, 608 exchange, 26, 37-38 functions of, 37-38,40, 112,126, 199,416, 600, 627, 705 rearrangements, 606-607 Alkyl halides, 600, 602-605 Alkyl naphtofuran, 271 Alkyl nitriles, 676 Alkyl vinyl ether, 294 Alkylation, 173, 192-193, 252, 263-264, 267, 282, 313, 387, 391-393, 400, 404, 409, 523, 541, 580, 590, 593, 601-602, 611-612, 626, 647, 657 Alkylidene malonates, 649-651 Alkylnitrilium, 682-683 Alkyls, 52, 60, 78, 83-84, 110, 161, 183, 271, 527, 601,644,658,660,675 Alkynes, 18, 73, 76, 78, 88, 147, 149-150, 152, 154155, 157, 159-168, 170, 173-174,280,291, 293, 311-313, 315, 320, 358, 371-373, 382, 440, 562, 600, 602, 604-607 Alkynylcyclobutenones, 357 Alkynyls, 357-358, 360, 373 Allenes, 77-79, 215, 289, 293, 358, 372, 380, 463, 467 Allenyl vinyl ketones, 134 Allenyls, 132 Allochemical effect, 312 Allyl(s) benzene, 22 borane, 167 functions of, 128, 130, 132, 149, 168, 200, 506 ketones, 123, 141 lithiums, 73 silanes, 139, 141 trimethylsilane, 282 vinyl ketones, 123 ct-Methyl-2-phenylcyclopropanemethanol, 41 -42 Alstonerine, 166, 168-169, 172 Alumina, 154,258,428 Aluminum characterized, 39 chloride, 412 trichloride, 128 Ambruticin, 34 Amides, 16, 21, 63, 96-97, 109, 115, 119, 153, 167,

Index

311,314, 464-468, 510, 656, 661 Amines, 21, 51, 54, 58-59, 61,116, 153, 155,269, 286, 312, 395, 398, 511, 600, 602, 662, 665, 706, 708 Amino, generally acids, 52-53, 55, 62-63, 105, 164, 316, 395, 512, 532-533 enediynes, 214 groups, 55-56 Aminobenzoic acid, 561 Aminocyclopropanes, bicyclic, 21 2-Amino-3,4-dibromo-6-methoxy-achloroacetophenone, 685 Aminodiol, 54 Aminoglycosidase, 513 Aminolysis, 63 Aminophenol, 691 Aminophenyl ketones, 677 3-Aminopyrroles, 580 Anaerobic conditions, 375, 382 Analgesics, 613, 679, 688, 693 Androgens and androgen receptors, 339, 503 Anesthetics, 3 Angiogenesis, 520, 567 Anguinomycin C, 296 Anhydrides, 16, 51, 236, 314, 349, 601, 613, 641, 708 Anilides, 606 Anilines, 628, 662, 677, 682 Anions Dieckmann condensation, 93-95, 104 Favorskii rearrangement, 117 propargylic, 73 Anisole, 619 Annulation, see Danheiser annulation; Dötz benzannulation; Robinson annulation cyclopentenone, 126 intramolecular, 699 Nazarov cyclization, 138, 143 processes, 72. See also Danheiser annulation ring-closing metathesis, 548 Thorpe-Ziegler reaction, 583 Vilsmeier-Haack reaction, 706-707 Weiss-Cook reaction, 187 Annulene, 377 Anthracene, 251-253, 259, 325-326, 348, 417 Anthracyclines, 241 Anthraquinones, 328, 334 Anthrenol, 327

731

Anthrone, 326-328, 334 Anthroquinone, 326 Anti-HBV agents, 19. See also Herpes virus Anti-inflammatories, 537, 679 Antibacterial agents, 47, 62, 101, 551, 583 Antibiotics, 45, 96, 106, 240, 242,297,264, 382, 513,526,561,649 Antibodies, 398-399 Anticancer agents, 103, 281, 583 Anticoagulants, 649 Antiestrogenic compounds, 262 Antitumor agents, 63, 240, 344, 382 Antiviral agents, 106 Antymycotics, 364 Arabinose, 533 Arenes, 209, 215, 217-218, 252, 260, 270,418, 437438, 603-604, 606, 613, 615, 681-619, 621622, 624-625, 628, 632, 645, 648,656,662663 Arenium, 409, 411,416 Argon, 91, 157, 174 Arianeosene, 20 Arnebil, 320 Arnebinol, 320 Aromatics five-membered carbocycles, 89, 112, 126, 133, 140 large-ring carbocycles, 430,436,439-442, 524 six-membered carbocycles, 199, 202, 212, 215, 238, 246, 252, 257-258, 260, 268-269, 288, 325, 350, 360, 370, 372, 381, 409, 419-420 in transformation carbocycles, 590-593, 600-601, 603, 623, 636, 639, 646-647, 655, 676, 680, 688, 690, 698-700, 704-705, 710-711 Aromatization, 200, 205, 240, 330, 360, 410-411, 581 2-[5-(Aroylpyrrolo]alkanoic acids, 679 Artemisinin, 528 Aryl(s) aryl-aryl coupling, 409, 414 Danheiser annulation and, 84 functions of, 64, 86, 133, 252, 255, 270-271, 291292, 311, 314, 320, 325, 366,410,434,440, 600, 633, 635-636, 649, 652, 654, 657, 714 glycines, 316 glycosides, 620 groups, 60, 112, 126, 161, 165,311 ketones, 612, 675-676, 678 nitriles, 675

732

Index

Aryl(s) (continued) oxides, 38 quinazolines, 684 Arynes, 711 Asbestos, 12-13 Aspirin, 688 Assoanine, 363 Asteriscanolide, 161, 168-169, 173, 474, 549-550 Asymmetric Diels-Alder reactions, 284-287, 295 Asymmetric Friedel-Crafts reactions acylation variables, 611-615 acylation mechanism, 610-611 alkylation variables, 605-610 description of, 600-601 experimental, 666-670 historical perspective, 601-602 key developments, improvements and utility, 615665 mechanisms, 603-605 Asymmetric Simmons-Smith reactions chiral auxiliaries, 24, 33 stoichiometric chiral ligands, 24, 34-35 sub-stoichiometric chiral ligands, 35-37 Asymmetry transfer, 133-134 Atropisomers, 317 Aurantiogliocladin, 359, 362 Autocatalysis, 35 Auxiliary, chiral. See Chiral auxiliaries Aviation industry, 608 Aza, 238, 377, 465 Aza-Robinson annulation, 392-394 Azadienes, 286-287 Azetidinone system, 62 Aziridines, 116 Azo compounds, 8 Azodicarboxylate esters, 62 Azomethine heterocycles, 46 Azulenes, 73, 81, 443-445, 583

Bacchopetiolone, 293 Bacillariolide, 506-507 Baeyer's voltage theory, 93 Baeyer-Villiger reaction, 190 Bardhan-Sengupta phenanthrene synthesis description of, 198 experimental, 207-208 historical perspective, 199 mechanism, 200-202

synthetic utility, 206-207 variation and improvements, 203-205 Barium isopropoxide, 295 Benzaldehyde, 595 Benzannulation, 360, 371 Benzazaine, 683 1,4-Benzediyl, 216 Benzenes, 104,203, 208, 211, 217, 255, 291, 293, 311, 342, 404, 412, 424, 426, 437-439, 509, 512, 530, 535, 539, 556, 567, 591, 593, 610, 614,617-618,628,679 1,4-Benzenediyl, 209 Benzenesulfonic acid, 61, 258 Benzfurnans, 705 Benzocoronenes, 417 Benzocyclobutenedione, 364-365 Benzodiazepines, 338, 596, 677 Benzofuran, 362 Benzoic acid, 646, 710, 712, 714 Benzophenanthridine, 363 Benzoporphyrins, 529 Benzoquinone, 236, 285, 314, 357, 359, 365, 413, 451,599-561 Benzothiadiazine, 104-105 Benzothiazepines, 581 Benzothiophenes, 259, 597 Benzoxapines, 53 Benzoxocinone, 19 Benzoyl groups, 255 Benzoylnitrile, 711 Benzoyloxyacetonitrile, 678 Benzoylquinine, 65-66 Benzyl(s) alcohol, 208 chloride, 592 functions of, 200, 271, 327, 370 groups, 438 phenol ketones, 679 Benzylbenzphenones, 253, 256-257 Benzylphenyl, 255 Benzylic acid, 111 Benzylidene, 652 1 -Benzyl-5-oxpyrrolidin-2-yl acetate, 668-669 Benzyloxy group, 138 2-Benzylpent-4-enoic acid, 267-268, 272-273 Benzylpiperidine, 401-402 2-Benzyl-4-(tert-butyldimethylsilyl)-3-ethyl-5methylfuran, 91-92 Benzynes,215, 289

Index

Bergman cyclization description 209 experimental, 219-220 historical perspective 209 mechanism, 209-211,370 synthetic utility, 218-219 variations and improvements, 211-218 Bergmann cycloaromatization, 374 Biapenem, 101 Bicyclic cyclopropanols, 18 Bicyclo[2,2,2]octane systems, 524-525, 533, 542, 554 Bicyclo[3.1.0]Kulinkovich-de Meijere reaction, 21 Bicyclo[4.1.0]heptan-2-one, 41 Bifurcarenone, 190 Bimolecular reactions, 578 BINAP, 287 Binding affinity, 339 BINOL, 625-627, 710 Biocides, 694 Biosynthetic pathways, 561 Biphenyl groups, 373 Bipyridine, 661 Biscembranoids, 566 Bischler-Napieralski isquinoline synthesis, 701, 706 Bislactim ester ethers, 619 Bis(oxazoline), 284-285 Bis(trifluoroacetoxy)-iodobenzene (BTIB), 293Bisoxazoline (BOX), 630, 634-635, 643, 648-650, 652-656 Bisphosphane-l,2-diaryl diyne, 213 Black reaction mixture, 21 -22 Blanc chloromethylation reaction description of, 590 experimental, 597-598 historical perspective, 590-591 mechanism, 591-592 synthetic utility, 594-597 variations and improvements, 592-594 Bogert-Cook reaction cyclization, 201,204 description of, 222 experimental, 233-234 functions of, 199 historical perspective, 222-224 mechanism, 224-226 selectivity, 226-231 synthetic utility, 231-233 variations, 231-233

733

Bonds C-C, 94, 181,380,410-411,683 C-H, 37, 434-438, 605, 683 C3-C4, 45 C-X,25, 27 electrophilic, 72 N-0,281 S-C, 332 Boron fluoride, 288 trifluoride etherate, 138, 140 trihalides (BX3), 609 Boronate groups, 311 Bradsher cycloaddition description of, 236 experimental, 248-249 historical perspective, 236 mechanism, 237-238 synthetic utility, 239-248 variations and improvements, 238-239 Bradsher reaction description of, 236, 251 experimental, 248-249, 264-265 historical perspective, 236, 251-252 mechanism, 237-238, 252-257 synthetic utility, 239-248, 260-264 variations and improvements, 238-239, 257-260 Branimycin, 526 Breast cancer, 260, 262, 553 BrefeldinA, 168-169, 171 Brevisamide, 296 Bromide, effects of, 15, 27. See also Bromination Bromination, 89, 191-192, 707 Bromine, 2, 203, 254 Bromobenzene, 347,428 Bromobenzylaldehydes, 645 3-Bromo-3-methyl-2-butanone, 110 Bromoform, 32 Bromoketones, 20, 112 10-Bromo-2,3,6,7,14,15,18,19octakis(ddecyloxy)trinaphtho[l,2,3,4fgh:\',2'3',4'-pqr:l',2',3',4'za^jtrinaphthylene, 421 Bromotitanium(IV) triisopropoxide, 19 Bransted acid, 129, 137,144, 268, 287, 602, 604605, 609, 611, 615, 623-626, 630-631, 639, 646-648 Bransted cocatalysis, 645 Buchner-Curtius-Schlotterbeck reaction, 424

734

Index

Buchner reaction asymmetric, 441-443 C-H insertion reaction vs., 434-438 description of, 424 experimental, 449 historical perspective, 424-426 macrocyclic 438-440 mechanism, 426-427 synthetic utility, 443-448 tandem alkyne insertion, 440-441 transition metal-catalyzed, 427-434 Bulky esters, 96 Butadiene, 10 1,3-Butadiene, 275 Butanol, 43, 97 Butenolide, 634 Butenones, 366 Butterfly-type transition, 26 Butylations, 606 2-Butyl-4-methoxynaphthalen-1 -yl-acetate, 321 -322 Butyraldehyde, 645 Butyrolactones, 510-511, 531, 548 CalanolideA, 679 Calicheamicin, 218-219 Calystegine A7, 535 Calystegine B 2 , 534 Camphor, 625 Camphorquinone, 183 Cancer, see specific types of cancers cell lines, 536 therapies, 212, 506, 520, 536, 553 Caponellene, 478 Caprolactamate, 440 Carbacephem, 96-97 Carbapenem, 95, 101 Carbasugars, 534, 547. See also Sugars Carbazoles, 316 Carbenes,59, 111, 153,287,311-313,315,317, 360,432, 438 Carbenoids, 24-26, 30, 38-40, 427, 430 2-Carbethoxycyclopentanone, 107 Carbinols, 251-252,447 Carbocations, 123-124, 134, 200-202, 602, 604-606, 683 Carbocycles, see Five-membered carbocycles; Large-ring carbocycles; Six-membered carbocycles; Three-membered carbocycle characterized, 524-526, 531, 535, 545

four-member. See Staudinger ketene-imine cycloaddition ring-closing metathesis, 532, 542, 549, 551-552, 556-557, 567 Carbocyclic(s) enol ether, 509 ring-closing metathesis, 548, 554, 561, 566 sugars, 339 systems, 514-517, 519, 521 Carbodiimides, 45 Carbohydrates, 339, 402, 512-514, 535, 556 Carbolines, 639, 644, 646 Carbon, see Carbon bonds atom, 72,133-134 dioxide, 300, 601, 688-690, 692-693 disulfide, 342 effects of, 47, 56, 78, 133, 148,155, 157, 181, 185, 187-188, 193, 199, 205, 239, 255, 369, 399,430 monoxide, 147-148, 150, 152, 154, 157, 160, 163, 171,310,311,432 Carbon bonds carbon-carbon (C-C), 94, 181, 380, 410-411, 683 carbon-cobalt, 149 carbon-hydrogen (C-H), 37, 434-438, 605, 683 arbon-nitrogen (C-N), 9 carbon-phosphorous, 280 Carbonates, 16,97,460 Carbonyl(s) characterized, 33, 63, 73, 94,110, 128, 150, 156, 173-174, 181-182, 186, 292, 326, 331, 351352, 389, 594, 615,618, 623-625, 630, 641, 643, 648, 654, 700, 702 group, 10, 14,45, 147-148,255 Carboprostacyclin, 189 Carboxyazoles, 692 Carboxy groups, 691 Carboxyindole, 692 Carboxylase, 694 Carboxylates, 79,100,199, 447 Carboxylation, 688, 692, 694 Carboxyl group, 710 Carboxylic acid, 16, 52, 55, 93, 109-111, 272, 345, 348,351,424,601,656 Carboxylic groups, 271 Carboxyls, 51 Carboxynapthalene, 714 Carcinogenic agents, 334 Carcinogenicity, 252, 260-262, 592

Index

Carcinogens, 257, 261, 682 Carissone, 516 Carvone, 90-91 Carvonecamphor, 451, 453 Cascade reactions, 140, 293-295, 297 Cassaine, 302 Catalysis, 36, 59, 62, 72, 135, 329, 381, 626 Catalyst selectivity, 611 Cation(s) allylic, 136 cyclopentenylic, 122-123 exchange process, 609 Nazarov cyclization, 129-132 pentadienyl, 122-125, 143 silylvinyl, 72-74, 76 tropylium, 81-82 vinyl, 76-77 Cdc25B, 528 Cedrene, 168-169, 174 Cephalotaxine, 143 Cesium carbonate, 690 Chalcogenides, 605 Charette auxiliary, 42-43 Chelation, 34, 96, 119, 128, 213, 312, 347 Chemically induced dynamic nuclear polarization (CIDNP), 211 Chemoselectivity, 16, 25, 40, 567 Chiral auxiliaries asymmetric Simmons-Smith reactions, 24, 33 dioxaborolane, 25 Dötz benzannulation, 318 Evans-Sjogren, 57 Friedel-Crafts alkylation, 619 Kulinovich cyclopropanol synthesis, 18 Nazarov cyclization, 133-134 Pauson-Khand reaction, 157-158 ring-closing metathesis strategy, 511, 520, 541 Robinson annulation, 398 Staudinger reaction, 57-58 Chirality transfer, 134 Chiral ligands, bifunctional, 34 Chloranil, 203 Chloride(s) acid, 16, 50, 58, 61, 84 anion capture, 140 effects of, 27, 618 Chlorination, 3, 592 Chlorine, 254, 352 Chloroacetonitrile, 581, 681

735

Chloroaldehyde, 287 Chloroaniline, 681 3-Chlorobenzoic acid, 715 4-Chlorobutanoyl chloride, 666 1 -(4-Chlorobutyl)-4-methylbenzene, 666 Chloro groups, 329 Chloromethylation, 590. See also Blanc chloromethylation reaction 3-(Chloromethyl)benzo[b]thiophene, 598 Chloromethyl groups, 597 Chloromethylzine chloride, 27 Chlorotitanium triisopropoxide, 22 Chlorotitanium(IV) triisopropoxide, 15-16 Chlorovinylsulfoxide, 585 Cholesterol, 399, 404 Choline acetyltransferase, 518 Chromanol, 358 Chromatography studies, see specific types of chromatography Chromium carbenes, 312-313, 315,317 functions of, 157, 296, 309-311, 360-361, 438 Chrysene, 351,615 Cinchona alkaloids, 665 Cinchonidine, 263, 630-631, 667-668 Cinchonine, 630 Cinnamaldehydes, 703 Cinnamic acid, 451 Cinnamoyl, 563 Cinnoline, 710 c/.j-l,2-Dialkylated cyclopropanol, 15 cis-l,5-Dimethylbicyclo[3.3.0]octane-3,7-dione, 194 cw-23-Bis(hydroxymethyl)-12,3,4tetrahydrnaphthalene, 219 cis-2,3-Dimethyl-l,4,4a,10a-tetrahydrophenanthren9,10-dione, 304 cis-A-exo—Isopropenyl-1,9-dimethyl-8(trimethylsilyl)bicyclo[4.3.0]non-8-en-2-one, 91 cisjrans-1,3,4,5,6,7,8,8a-octahydroazulen-1 -one, 145 m-Tricyclo[6.3.0.0]undec-l(8)-en-2-one, 144 Citronellal, 567 Civetone, 566-567 Claisen condensation, 93-94, 474 Claisen rearrangement, 465, 542 Claisen/ring-closing metathesis, 510 Clavilactone B, 558

736 Clavirolide C, 561-562 Clavizeine, 247 Clavukerin, 89-90 Cleavage, 9, 31, 33, 55, 61-62, 105, 154, 218-219, 285, 362, 383, 461, 477-478, 613, 617, 647 Cobalt -alkyne complex, 159 -carbon bond, 150, 159 Pausen-Khand reaction, 148-152, 155, 159-160, 162, 165, 168, 170, 174 Cocatalysis, 605, 645-646 Coenzyme Q, 362 Column chromatography, 22-23, 66, 92, 220 Compactin, 526 Complexation, 438 Compound 14, 120 Compound 28, 708 Compound 30, 708-709 Condensation characterized, 4 de Mayo reaction, 474 Dötz benzannulation, 313 Friedel-Crafts reactions, 641, 647 ontramolecular, 579 Robinson annulation, 386 Weiss-Cook reaction, 187 Confertin, 445 Conrotation, 133-135 Conrotary closure, 8 Conversion rate, signifcance of, 2-3 Cope process, 188 rearrangement, 191 Copper, 88, 130, 135, 187, 280, 284, 428, 433, 629, 635, 652-654, 661 Corannulene, 350 Cornextins, 556-557 Counterclockwise rotation, 134 Coupling intramolecular, 18 reductive, 17 Cracking, 600, 608-609 Cresol, 347 Cribrostatin, 63-64 Cross-coupling, 292 Crossover, stereochemical, 7 Crystallization, 394, 402 CucuminE, 105, 552 Cumulene, 375-376, 382

Index Cuparene, 516 Cuprate, 187 Cupric oxide, 37 Curacin A, 31 Cyanide, 246, 680, 711 Cyano groups, 311 Cyanohydrins, 190-191 Cyanomethyllithium, 585 Cyanopyridine, 679 Cyclization, see specific types of reactions cascade reaction, 206 double reaction, 206 intramolecular, 9, 148 spontaneous, 64, 219 1,3-Cycloaddition, 9 Cycloadditions Bradsher, 236-248 formal, 140 impact of, 157 rate of, 237 step-wise, 72 Cycloaromatization, 215, 360, 374-375, 377 Cyclobutane, 76 Cyclobutanone, 45, 114-115 Cyclobutenediones, 366, 378-379 Cyclobutenes, 47, 378-379 Cyclobutenones, 310-312, 359-360, 362-364 Cycloctanoid, 550 Cyclodehydration, 238, 252, 257-258, 263, 328-329, 399 Cyclodehydrogenation, 418-419 Cycloheptadiene, 89 Cycloheptane, 156 Cycloheptenone, 89-90 Cyclohexadiene, 109, 211, 216, 369 Cyclohexane, 275, 277-278, 295 Cyclohexanone, 78, 392 Cyclohexene, 24, 32, 203, 282 Cyclohexyamine, 155 Cyclohexylaldehyde, 83 Cycloisomerization, 267 Cyclooctene, 283, 551, 553 Cyclooctonoids, 544-547 Cyclopentadiene, 451 Cyclopentanes, 73 Cyclopentanones, 98, 126, 137, 141-142, 310-311 Cyclopentene synthesis, 79-82 Cyclopentenol, 103 Cyclopentenone, 77, 105, 122, 129, 134, 139, 148,

Index 150, 153-155, 157-159, 161, 182-183 Cyclopentylmagneium chloride, 22 Cyclophanes, 59, 316 Cyclopropanation reactions, 14, 17,425-432,437, 440-441. See also Kishner cyclopropane synthesis; Kulinovich cyclopronation synthesis; Simmons-Smith cyclopropanation Cyclopropane characterized, 2-4, 681 formation, 112 olefins compared with, 10 synthesis, 25 Cyclopropanol, 14-21, 540 Cyclopropene, 164 Cyclopropylamine, 21 Cyclopropylcarbinyl cation rearrangement, 142 3-Cyclopropyl-5-phenyl-2-pyrazoline, 12-13 Cycloproteins, 7-8 Cytochrome P-450, 682 Cytotoxicity, 219, 551 Danheiser annulation aromatic, 72 description of, 72-73 historical perspective, 73-75 mechanisms of, 75-78 synthetic utility, 78-89 total synthesis of natural products, 89-92 Darzens synthesis, of tetralin derivatives description, 267 experimental, 272-274 historical perspective, 267 mechanism, 267-268 synthetic utility, 271-272 variations and improvements, 268-270 Daucene, 459 DCM, 655-657 Deacetylation, 442 Dealkylation, 606-608 Dean-Stark trap, 259-260 Deazetation, 8 Debenzoyltashironin, 302 Debromination, 192 Decaline, 380 Decalin system, 295-298, 400-401, 527 Decarbonylation, 293 Decarboxylation, 93, 97, 104-105, 181, 183, 185, 187, 192-194, 267, 269, 272, 578, 582-583

737

Decomplexation, 215, 361 Decomposition, 7-8, 10, 187, 430, 441, 447, 551, 712 Dehydration, 99-100, 182, 192-194, 251, 387, 394, 701-702 Dehydration-acylation, 639 Dehydroaromatics, 370 Dehydro-Diels-Alder reactions, 293 Dehydrogenation, 198, 200, 203-204, 207, 271, 327, 337, 348-352, 444 de Mayo reaction a-diketones, 455-475 description of, 451 experimental, 486 historical perspective, 451-454 mechanisms, 454 regioselectivity, 454-455 synthetic utility, 475-486 Demetalation, 360 Demethylation, 301 Dendralene, 292 Denitration, 290 Denmark's modification, 27 Density functional therapy (DFT), 155, 238, 358, 371,374,377,633 Deoxyfrenolicin 365 Deoxygenation, 186 Deoxystreptamine, 513-514 Deoxysymbioimine, 299 Deprotection, 31, 106, 186, 189, 301, 366, 534, 561, 635 Deprotonation, 40, 96, 111,117, 136, 173, 268, 387, 411 Desilyation, 75-77, 81, 86, 289, 447 Desoxygaliellalactone, 299 Deuterium, 208, 211, 214-215, 325, 377, 652 Diabetes, 547 Dialkoxytitanacyclopropanes, 14 Dialkyl amides, 698 amines, 702 aminopyridine, 59 functions of, 601 nylarenes 212 zinc, 26 Diaminocyclohexane, 60 Diarylalkane, 251 Diarylmethane, 238, 259 Diastereoisomers, 31

738

Index

Diastereomeric analysis, 135 Diastereoselectivity Buchner reaction, 436, 442 de Mayo reaction, 462 Favorskii rearrangement, 118 Kulinovich cyclopropanol synthesis, 15-16 Nazarov cyclization, 137, 140 Pauson-Khand reaction, 157-158, 167, 170, 172 ring-closing metathesis, 533 Simmons-Smith cyclopropanation, 29, 32-33, 35, 38 Staudinger reaction, 53-56 Diazoacetamide, 437 Diazoalkane, 9, 38-40 Diazocarbonyl, 51-52 Diazo compounds, 25, 65 Diazoketones, 187,428-429,440 Diazomethane, 26, 192 Diazopropane, 9 Diazotization, 600, 602 Dibenzanthracene, 330 Dibenzylideneacetone, 122 Diborane, 193 Dibromides, 4-5 Dibromoaniline, 681 Dibromo esters, 104 l,3-Dibromo-2,2-dimethyl propane, 5 Dicarbonyls, 454 Dicarboxylation, 691 Dication, 199 Dichlorobenzene, 300 1,4-Dichlorobenzene, 208 Dichlorocyclopropylmethanol, 142 2,3-Dichloro-5,6-dicyano-1,4-benzoquinone (DDQ), 203,352,413,529 Dichloromethane, 24, 30, 174, 247 Dichloropropane, 2-3 Dicobalthexacarbonyl, 147 Didehydroprenylindole, 133 Dieckmann condensation description of, 93 experimental, 107 historical perspective, 93 mechanisms of, 93-97, 597 standard method, variations, and improvements, 97-101 synthetic utility, 101-107 Diels-Alder adduct, 112 Diels-Alder cycloaddition/ring-closing metathesis,

525 Diels-Alder reaction description of, 275 experimental, 303-304 historical perspective, 275-276 mechanism 164, 181, 236-237, 239, 276-279, 448 ring-closing metathesis (RCM), 527 synthetic utility, 288-303 transannular, 563 variations and improvements, 279-288 Dienediyne, 377 Dienes Darzen's synthesis of tetralin derivatives, 270, Diels-Alder reaction, 275-276, 278-279, 282-283, 288, 291-294, 296 ring-closing metathesis (RCM), 459, 507, 512, 520, 524, 529, 532-533 535, 541-542, 544, 550, 556, 564 Vilsmeier-Haack reaction, 703 Dienones, 140, 360 Dienophiles, 236-237, 275, 277-281, 284, 288-290, 293, 295 Diens, 236 Dienyl dihydropyrans, 521 Dienynes, 123,217,293 Diepoxin, 345 Diethyl ether, 9 Diethyl 6-fluoro-4-vinyl-3,4-dihydronaphthalene2,2(l#)-dicarboxylate, 273-274 Diethyl 1,2,3,4-tetrahydro-4-methyl-4phenylnapthalene-2,2-dicarboxylate, 273 Diethylzinc, 24, 32, 41-42 Diflunisal, 688, 694 2,2-Difluoro-3-hydroxy-7,7-dimethyl-cyclooct-4enone, 570 Dihalo compounds, 2 Dihaloalkanes, 37, 609 Dihalocarbenes, 25 Dihaloketones, 117 Dihydranthorol, 325, 327 Dihydroanthracene, 348 Dihydroanthranol, 330 2,3-Dihydroazulen-l(4H)-one, 449 Dihydrobenzoxazone, 95 Dihydro-epi-dexyarteannuin B, 527 Dihydrofurans formation, 87-89 functions of, 73 synthesis, 83-85

Index

Dihydronaphthalene, 86, 242 Dihydrophenanthridinediols, 363 Dihydropropyranones, 287 Dihydropyrans, 287, 294 Dihydropyrazinones, 53 Dihydropyrrole synthesis, 73, 85-86, 88 Dihydroxylation, 512 Diimide, 285 Diiodomethane, 24-26, 37 Diisobutylaluminum hydride (DIBAL), 469 Diisopropylethylamine, 59 Diketo, 386 Diketones, 246, 387, 452, 455-468, 477 Dimerization, 51, 60, 192, 293, 565, 578, 692 Dimers, 133 5,8-Dimethoxy-3,4-dihydro-2H-naphthalen-l-one, 353 Dimethoxyindole, 680 5,6-Dimethoxy-2-methyl-2,3-dihydro- l//-inden-1 one, 666-667 10-Dimethoxymethyl-3,4,4a,5,10,1 Oa-hexahydro2//-benzo[g]chromen-5-yl)-(2,4-dinitrophenyl)-amine, 248-249 4-(2 ' 5 ' -Dimethoxyphenyl) butyric acid, 353 -4-oxobutyric acid, 353 2,4-Dimefhoxy-6,7,8,9tetrahydrobenzo[g]quinazolin-6-ol, 219-220 2,3-Dimethoxy-4-(3-trimethylsilyl-1 -propynyl)-4trimethylsiloxycyclobut-2-en-1 -one, 366-367 2,3-Dimethoxy-5-trimethylsilyl-6((trimefhylsilyl)methyl)-l,4-benzoqui-none 366-367 Dimethylaminoanisole, 656 Dimethylation, 187 Dimethylcyclopropane, 5, 8 2,2-Dimethylmethylenecyclopropane, 11 1,2-Dimethyl-3-ethylcyclopropane, 5 Dimethyl groups, 173, 663 2,2-Dimethylisopropylidenecyclopropane, 11 Dimethylphenanthrene, 337 Dimethylpyrazolines, 8 Dimethylsulfoxide, 155 Dimethyl tetrahydronaphthalene, 268 1,1-Dimethyl tetralin, 234 Dinitrile, 578, 584 Dinitrobenzoyl, 614 Dinitrophenyl, 240 Diolefin, 562

739

Diols, 5, 54, 61,261,442 Dioxaborolane auxiliaries, 25 functions of, 42 Dioxane, 133,690 Dioxinone, 470 Dioxins, 531 Dioxolenones, 469-471 l,6-Dioxo-8a-methyl-1,23,4,6,7,8,8aoctahydronaphthalene, 406-407 Dipeptides, 35 Diphenylmethane, 208 Dipoles, 302 1,2-Dipropynylcyclopentene, 212 Diradicals, 7, 9, 214,219, 360-362, 369, 371-373, 375-376, 378, 380, 383 Directing group, Robinson annulation, 399-400 Dissociation energy, 605 Dissociative mechanisms, 109 Distillation, 5-6, 9, 12-13,43 Disulfonamides, 35 Diterpenes, 562 Diterpenoids, 538 Di-thiol ester, Dieckmann condensation, 97-98 Diversifolin, 559-560 Divinyl dichloride, 142 ketones, 123, 126-127, 129 3,5-Divinyl-l-pyrazoline, 9 Dixoaborolane, 34 Diyne, 18,375 DNA cleavage, 219, 378,382-383 functions of, 218 supercoiled, 362, 383 Doazoalkanes, 425 Dolabellane family, 562 Domino-Knoevenagel-hetero-Diel-Alder reaction, 294 Dopamine agonists, 346 Dötz benzannulation reaction (DBR) description, 309 experimental, 321-322 historical perspective, 309-310 mechanism, 310-311 synthetic utility, 315-321 variations and improvements, 311-315 Dragmacidin, 681 Drug development process, 513

740

Index

Dynemicin, 219 Dysinosin A, 525-526 Eight-membered rings, ring-closing metathesis strategy, 544-555 Elatol,521 Elbs reaction description, 324 experimental, 324 historical perspective, 324-325 mechanism 238, 325-327 synthetic utility, 334 variations and improvements, 328-334 Electrocyclization, 112, 125, 130, 136, 140-143, 310 Electron donating groups, 277 Electron-donating group (EDG), 47-48, 125, 128, 130, 160, 199, 202, 277, 621, 635-637, 641, 657, 679-680, 706 Electron-releasing groups, 606 Electron-withdrawing group (EWG), 47-48, 129130, 160, 162, 173, 202, 269, 279, 596, 612, 618, 621, 625, 636-637, 641-642, 657 Electrophiles asymmetric Friedel-Crafts reactions, 601 Blanc chloromethylation reaction, 591, 593 electrophilic alkylation, 409, 590-591, 675 electrophilic aromatic substitution (EAS), 198, 602, 604 electrophilic attack, 252 electrophilic coupling, 677 electrophilicity, 27, 37, 678 Eleutherobin, 559 Eleuthesides, 558 Elimination, 14, 329-332, 600 Ellacene, 193 Eluetherins, 319 Enamide, 637, 668 Enamines, 35, 52-53, 401, 579, 582 Enantiocontrol, Friedel-Crafts reactions, 649, 657658, 660 Enantiodifferentiation, 631 Enantiomers, 34, 617, 622-623, 652 Enantiopure, 157 Enantioselectivity Bradsher cycloaddition reaction, 244 Büchner reaction, 442 Danheiser annulation, 88 Diels-Alder reaction, 275, 287, 292, 298 Friedel-Crafts alkylation, 623, 625,630, 635-637,

639, 641, 644, 651-653, 655-657, 659, 661, 665 Kulinovich cyclopropanol synthesis, 15-16, 18 Nazarov cyclization, 135-137 Pauson-Khand reaction, 157 ring-closing metathesis, 513, 520, 546, 555 Robinson annulation, 398 Simmons-Smith cyclopropanation, 32, 35, 38 Staudinger reaction, 52-61 Thorpe-Ziegler cyclization, 585 Enantiospecificity, 363 Endocyclic reactions, 167 Endo:exo- selectivity, 32 Endothelin receptor antagonists, 568 Enedione, 586 Enediynes, 209, 211-213, 216, 218-219, 360, 374 Energy barriers, 562. See also Activation energy Enol(s) esters, 455-460, 472-473 ethers, 24, 35, 158,290,311 functions of, 111, 133, 141, 182,1 87, 192-193, 238,244,451 -olefin reactions, 452 Enolates, 47, 52, 94-95, 111-112, 117, 136, 140, 185,264,285 Enolization, 27, 52 Enones, 20, 164, 186, 205, 280, 339-340, 431, 506 Entropy, 154 Enynes allenes, 371-374, 378, 380-381, 383 functions of, 157 ketenes, 356-358, 360 Enynol acetate, 142 Enzyme inhibitors, 543 Epilycopodine, 451, 475-476 Epimerization, 141, 174 Epimers, 459 Epoxides, 111,118, 262, 558, 600,602, 622-623 Epoxydictymene, 168-169, 171-172 Ergosterol, 281 Ervitsine, 543 (E)-6-( 1 //-indl-3-yl)-1 -( 1 -methyl-1 //-imidazol-2yl)hex-2-en-l-one, 669-670 Esterification, 185, 351 Esters five-membered carbocycles, 75, 79, 93-97, 109110, 129, 131, 153, 161, 163, 167, 184-185 four-membered carbocycles, 52, 55, 62-63 large-ring carbocycles, 460-463

Index

three-membered carbocycles, 14, 16-17, 19,21, 29 six-membered carbocycles, 240, 269, 287, 311, 314-315 in transformation of carbocycles, 596, 602, 619, 628, 636, 656-657, 694 Estradiol, 262 Ethane gas, 14 Ethanol, 3-5, 12,46,97,714 Ethers five-membered carbocycles, 64, 153, 155, 158, 165-166, 172 six-membered carbocyles, 238, 242,294, 311, 403 three-membered carbocycles, 16, 22, 24, 27, 29, 33,41 in transformation of carbocycles, 600, 602, 617, 619, 625 Ethoxide, 581 Ethoxyethanol, 715 Ethyl acetate, 17, 22-23 Ethylation, 603 Ethylbenzene, 138 Ethylenes, 27, 117,536,715 Ethylformate, 399 l-(2-Ethynylphenyl)hept-2-yn-l-yl pivalate, 384 Ethyl vinyl ester, 287 ether, 242 ketones, 393 Eudaline, 271 Eudesmol, 271 Eunicellins, 299 Europium, 281, 296 Evaporator, rotary, 22-23 Exothermic reactions, 12, 41 Extracts, 22, 42, 145

Factor Vila, 525 Favorskii rearrangement description of, 109 experimental, 119-120 historical perspective, 109-111 mechanisms of, 111-114 synthetic utility, 116-119 variations, improvements and modifications, 114116 Fermentation, 425

741

Ferrier cyclization, 339 Ferrocenyl group, 358 Ferruginol, 206 Fischer carbenes, 313, 361 Five-membered carbocycles Danheiser annulation, 72-92 Dieckmann condensation, 93-107 Favorskii rearrangement, 109-120 Nazarov cyclization, 122-145 Pauson-Khand reaction, 147-176 Weiss-Cook reaction, 181-195 Five-membered rings, ring-closing metathesis strategy, 494-509 Flash chromatography, 151 Flavonoid, 678 Fleming-Tamao oxidation, 288 Fluoral, 625 Fluoride, 90, 106,474,618 Fluorine, 261-262, 264 Fluoroanthracenylmethyl cinchonidine, 263 Fluorobenzene, 413 Fluoroketone, 330 lO-Fluoro-3-methylcholanthrene, 334 Fluostatin C, 296 Flustramine B, 665 Food contamination, 682. See also Herbicides; Pesticides Formal [3 + 3] Danheiser annulation, 86-87 Formaldehyde, 294, 590, 595-596 Formamidate, 46 Formanilide, 698 Formyl groups, 399-400, 614 Formylation -cyclization sequences, 704, 706-707 functions of, 259, 705, 707 Forosamin, 294 Four-membered carbocycles. See Staudinger ketene cycloaddition FR-01483, 522 FR-900848, 32 Fractionation, 13 Fragmentation Beckmann, 507 Buchner reaction, 431 de Mayo reaction, 456-459, 464, 466, 470, 474, 476 /-eiro-Mannich, 464 ring-closing metathesis, 557 Free radicals, 2, 370, 647

742

Index

Freund reaction description of, 2 experimental, 5-6 historical perspective, 2 mechanisms of, 2 variations and improvements, 3 synthetic utility, 3-5 Friedel Crafts acylation alkylation vs., 611-612 effect of, 206, 342-346, 348-349, 351, 675, 701 Friedel-Crafts alkylation, 89, 267, 593 Friedel-Crafts reactions, 84, 238, 409-410, 413, 590. See also Asymmetric Friedel-Crafts reactions Fries rearrangement, 468 Frondsins, 539 Frontier molecular orbital (FMO), 237-238, 277 Fujimoto-Belleau reaction description, 336 experimental, 340 historical perspective, 336-337 mechanism, 337-338 synthetic utility, 339-340 variations, improvements, and modifications, 338-339 Fumagillin, 520 Functional groups, 24, 27, 29, 31, 62, 153, 157, 160, 534, 590, 606, 608, 612, 703 Furans characterized, 73, 112, 241, 271, 311, 595-596, 629, 634, 705 Danheiser annulation, 89 synthesis, 83-85 Furanocourmarins, 316 Furukawa modification, 24, 26,41-43 reagent, 30 Furyl, 183 Fusicoccane synthesis, 170 Galactopyranosides, 546 Galactose, 513 Gas chromatography (GC), 10, 43 Gas-phase pyrolysis, 210 Geraniol, 40 Gibberellin, 448 Glucose, 513 Glyceraldehyde, 53, 57 Glycerols, 557

Glycines, 252, 263-264, 316 Glycols, trimethyl, 2, 4 Glycosidase, 512 Glycosides, 281 Glyoxal, 193, 627 Glyoxylates, 628 Gold, 381-382 Gossypol, 693 Green chemistry principles, 160 Grignard reagents, 14-16, 18-19, 246, 336-337, 340 Ground state molecules, 29 Guanacastepene, 118 Guanine, 19 Gymnodimine, 523 Gymnomitrol, 188 Hainanolidol, 445-448 Hajos-Wiechert reaction, 394-396 Halenaquinone, 299 Halicholactone, 30-31 Halides, 51, 73, 110, 112-114, 600, 618 Halocarbenes, 403 Halogenation, 203 Halogens, 254, 609 Halohydrins, 522 Haloketimines, 109 Haloketones, 109 Halomethlzinc reagent, 34 Hamicane, 641 Hamigeran, 347 Hammett linear free energy, 238 Harringtonolide, 445-448 Hass cyclopropane process, 3-4 Hasubanonine, 528 Haworth reaction description, 342 experimental, 352-353 historical perspective, 342-343 mechanism, 343 synthetic utility, 344-352 variations and improvements, 343-344 Haworth syntheses phenanthrene, 342, 349-352 tetralone, 344-349 Haworth-type reaction, 611 Heavy metals, 203 Heliannuols, 19 Hemiketalization, 561

Index Hepatitis C virus, 105 Herbicides, 536 Herpes virus, 347 Heteroarenes, 632 Heteroaromatics, 590, 594, 600, 699, 704 Heteroatoms, 133, 213-214, 279-280, 635 Heterocycles, 45, 321, 333, 692 Hetero Diels-Alder reaction, 280-281 Heterodienes, 280 Heterodienophiles, 280 Hexacyclotetradecane, 117 10(9//)-1,2,3,4,41,1 Oaa-hexahydro-1 a, 4aadimethylphenanthrone, 207-208 2,3,3a,5,6,8a-Hexahydro-1//,4//-7-oxacyclopenta[a]inden-8-one, 145 Hexa-pen'-hexabenzocoronenes (HBCs), 414-418 Hexo-saminidase, 513 Highest occupied molecular orbital (HOMO), 237, 276, 279, 664 High-performance liquid chromatography (HPLC), 164 Himachalene, 476 Himandrine, 298 Himgaline, 298 Hirsutene, 158, 168-169,480-481 HIV characterized, 567 drugs, 174 integrase inhibitors, 694 treatments, 174,679 Homoallyl alcohol, 531 Homofascaplysin C, 707 Homologating/homologation, 183, 623 Homo-Robinson annulation, 403 Hopf cyclization, 217 Houben-Hoesch reaction description of, 675 experimental, 684-685 historical perspective, 675-676 mechanism, 676-677 synthetic utility, 675, 677-684 variations and improvements, 677 Hunigs base, 658 Hybridization, 219 Hydrazides, 283 Hydrazines, 11-13, 55 Hydrazones, 55 Hydrides, 140, 604, 702 Hydrobromic acids, hydrobromic, 2, 4

743

Hydrocarbons, 2 ,4-6, 147, 209, 246, 252, 593-594, 608 Hydrochloric acid, 590 Hydrochloride, 51 Hydrogen atom, 378, 383 bonds/bonding, 452, 637, 642, 646 bromide, 5, 269 donor, 209 fluoride, 258, 268, 272-273 functions of, 37, 127, 149, 170-171, 219, 254, 327, 380, 600, 627 sulfide, 702 transfer, 203 Hydrogenation, 187, 203, 349, 442, 658 Hydrogenolysis, 28, 534, 565 Hydrolysis, 51, 102, 123, 129, 142, 185-186, 190, 192-194, 240, 251, 269, 290-291, 424, 442, 476, 582-583, 676, 702, 714 Hydrophobie effects, 154 Hydroquinones, 359, 363 Hydrostannylation, 135 Hydroxides, 97 Hydroxy acids, 53, 688 alkylation, 631 benzoic acid, 694 carbonyl, 656 coumarins, 649 enone, 655 esters, 199,628-629 groups, 201, 405 methylene group, 399 quinones, 366 3-Hydroxy-l,2-benzflurenone, 413 4-Hydroxyindole, 668 Hydroxyl(s) acids, 688 amine, 702 groups, 29, 31,262, 692, 701 functions of, 203, 655, 691 lactams, 643 methylene group, 399 Hydroxylation, 624 Hydroxymethylglutaryl coenzyme A (HMG-CoA) reductase, 352, 526 11-Hydroxy-O-methylsterigmatocystin, 682 8-Hydroxy-7-quinaldic acid, 695 8-Hydroxyquinaldine, 694

744

Index

3-Hydroxy-4,6-substituted-3,3a,4,5,8,9,9a,9boctahydro-1 //-cyclopenta[a]naphthalen7(2H)-one, 340 Hydrozirconation, 16 Hyperconjugation effect, 254 Illudin C, 707 Imidates, 115 Imidazole, 661 Imides, 16,467 Imines, 45-48, 50-52, 56-60, 115-116, 464, 579, 615,623,626,631-648 Iminium, 47, 238, 282, 460, 664, 699-700 4-Imino ß-lactam, 45 Iminoesters, 88 4'-Imino-10-oxospiro[anthracene-9,l'cyclohexane]-3-carbonitrile, 587 Incarvilline, 168-169 Indazolonone, 712 Indenes,310,312, 372 Indium, 59 Indoles in large-ring carbocycles, 555 six-membered carbocycles, 246, 311,316-317 three-membered carbocycles, 21 in transformation of carbocycles, 615, 621, 623, 625-632, 637, 639-642, 649, 651, 653-656, 660, 662-663, 665, 668-669, 680-681, 692, 705 Indoline, 360 Indolylcyclopropylamine, 21 Indones, 663 Infection, treatment of, 45 Inflammatory diseases, 539 Ingenol, 452, 485-486, 557 Inside-outside ring system, 557-558 Intramolecular Diels-Alder reactions, 287-288, 299302 Inverse electron demand Diels-Alder reaction, 281283, 294, 302 Inversion, single, 8 Invertoyuehchukene, 133 Iodides, 2-3, 314, 448 lodine, 18 Iodobenzene, 292 Iodolactonization, 448 Iodomethyl zinc iodide, 25 trifluoroacetate, 38

Ionization, 142 Iridium, 157 Iron, 137-139, 157,215 Irradiation impact of, 212, 455, 457, 459,462-463, 465-466, 469, 474, 477, 546 microwave, 314 ultraviolet, 312 Isoborneol, 158 Isobutene, 173 Isocaryophyllene, 453 Isoclavukerin, 89-90 Isocomene, 185 Isodityrosines, 316 Isomerization, 49, 88, 90, 129, 131, 186, 460, 554, 560, 600, 608-609, 637 Isomers, 40, 42, 76, 109, 122, 126, 174, 204-205, 288, 317, 325, 357, 400,402,435,438,440, 456, 550, 560, 564, 567, 569, 606, 619, 622, 663,680 Isoprene, 277 Isopropyl functions of, 271 idenecyclopropane, 11 trimethylacetate, 110 Isoquinolinones, 436 Isoquinolone, 701 Isothiochroman-4-one, 375 Isotopes, 111, 376 Isotubaic acid, 693 Isoxazoles, 73, 86, 89, 653 Isoxoazoline, 652 Jahn-Teller distortion, 630 Japanese hop ether, 168-169, 174 Juglomycin A, 318-319 Kainicacid, 168-169, 172 KanamycinB, 513 K-channel blocker, 665 Kelosene, 115 Kempane, 540-541,563 Kendomycin, 320, 568-569 Kerr's syntheses, 174 Ketenes, 42-52, 55-60, 111, 311, 601 Ketimine, 253 Keto acid, 342, 348 Ketoaldehydes, 703 Ketocarbenoid, 434

Index

Ketoesters, 101-104, 131, 468-475, 648-650 Ketols, 123, 387, 396-397, 656, 661 Ketones five-membered carbocycles, 72-77, 79, 88-90, 109-111, 114, 118, 122-124, 126-127, 129, 132-134, 141, 153, 162-164, 172, 186, 189, 191 four-membered carbocycles, 63 large-ring carbocycles, 430, 447, 455, 461, 578, 582 six-membered carbocycles, 238, 249,253,255, 257, 284, 289, 292, 311, 325, 327-328, 331332,338,381-382,388,399 three-membered carbocycles, 7, 10, 12, 20, 27 in transformations of carbocycles, 600, 602, 614, 623, 626, 630, 656, 665, 679, 704 Ketonitrile, 578 Keto-substrate cyclization, 203 Kinabalurine, 164 Kinetics, 9 Kishner cyclopropane solution description of, 7 experimental, 12-13 historical perspective, 7 mechanisms, 7-9 synthetic utility, 10-12 variations and improvements, 9-10 Kobayashi system, 36 Kolbe-Schmitt reaction description of, 688 experimental, 695-696 historical perspective, 688 mechanism, 689-690 synthetic utility, 691-694 variations and improvements, 690 Kugelrohr distillation, 43 Kulinkovich cyclolpropanation. See Kulinkovich cyclopropanol synthesis Kulinkovich cyclopropanol synthesis description, 14 experimental, 21 -23 historical perspective, 14 intermolecular reaction, 22 mechanism, 14-15 synthetic utility, 16-21 variations and improvements, 15-16 Kulinkovich-de-Meijere reaction, 16 Kulinkovich reaction. See Kulinkovich cyclopropanol synthesis

745

Labeling deuterium, 214-215 isotopie, 689 Lactams, 46-51, 53, 55-56, 58-64, 96,436, 523, 533, 541, 641-644 Lactic acid, 57 Lactol, 190 Lactones, 45, 172, 268-269, 340, 456, 469, 508, 510-511, 531-532, 536-537, 548-549, 558, 565,616-617 Lactonization, 469 Large-membered rings, ring-closing metathesis strategy, 555-569 Large-ring carbocycles Büchner reaction, 424-449 de Mayo reaction, 451-486 ring-closing metathesis (RCM), 489-570 Thorpe-Ziegler reaction, 578-587 Lawsone, 366 Lepadiformine, 522 Leukemia, 506 Lewis acids, 16,36,72,99, 116, 122-123, 128, 137, 141, 144, 198, 269, 275, 279-280, 294, 299, 392, 409-410, 592-593, 601-606, 609, 612, 614-615, 618, 623-625, 630-631, 639, 648, 670, 676, 680-682 Lewis base, 663-664 Light-emitting diodes, 419 Lindlar reduction, 365 2-Lithionitriles, 585 Lithium aluminum hydride, 442 borohydride, 64 functions of, 313-314, 366, 380, 402, 442, 691 hydroxide, 174 iodide, 187 Loganin, 189-190 Longifolene, 477-478 Longithorone C, 568 Lowest unoccupied molecular orbital (LUMO), 163164, 237, 276, 279, 662, 664 Lysergic acid diethyamide (LSD), 246 Macrobicyclization, 299 Macrocycles/macrocyclization, 320, 562-564, 566, 568, 583 Macrolides, 516 Macromodel calculations, 211 Magellanine, 168-169

746 Magellaninone, 168-169 Magnesium, 15, 22, 42-43 Magnus model/hypothesis, 148, 170 Maleic acid, 203 anhydride, 236 Maleimides, 285 Malonates, 269, 272-273, 649-652 Malononitrile, 580 Manganese, 309 Mannich reaction, 404, 460 Mannitol, 513 Mannose, 339 Manzamine A, 242-244, 452, 483-484 Maritomol, 584 Medicinal chemistry, 19, 45, 63, 102, 401, 597 Meerwein quinazoline synthesis, 684 Melanin-concentrating hormone receptor I (MCHrl), 401 Meropenem, 101 Mesityl groups, 432 Mesyloxy group, 618 Metal(s) alkyl, 605 -carbene complex, 426 -carbon bond, 159 exchange reaction, 15 halides, 605 ions, 213-214 -metal bonds, 151 Metallacycles, 310 Metallocycles, 148, 150 Metathesis, ring-closing. See Ring-closing metathesis strategy Methacrolein, 82 Methanol, 88, 97, 208, 369, 714 2-(4-Methoxybenzyl)-l-napthoic acid, 258 Methoxy groups, 329, 620 8-Methoxy-4a-methyl-4,4a,9,10tetrahydrophenanthren-2(3H)-one, 405-406 Methyl(s) acetanilide, 698 bromide, 603 -5-(chloromethyl)furan-2-carboxylate, 598 cholanthrene, 330, 334 cyclopentanecarboxylate, 119-120 esters, 240, 650, 657 groups, 77, 170-171, 174, 186, 199, 238, 255256, 325, 372, 458, 590

Index

impact of, 254, 329, 352, 377, 660 indole, 657 iodide, 603 ketones, 386, 388 lithium, 338 perezone, 365-366 phosphonate, 339-340 propionic acid, 342 sarcophytoate, 566 vinyl ketone (MVK), 388, 391-392, 394-395, 400 Methylation, 187,347 1-Methylbutadiene, 277 2-Methylcyclopropane carboxylic acid, 31 2-Methyl-2,4-dibromopentane, 4, 6 Methylene functions of, 35, 94, 238 groups, 26, 40, 95 hydrogens, 458 4-Methylene-l-pyrazoline, 11 3-Methyl octahydrophenanthrene 207 2-Methylphenanthrene, 595 2-Methylpropene, 289 4-Methyl-tetrahydronaphthalene-2-carboxylic acid, 267 4-Methyl-1,2,3,4,-tetrahydronaphthalene-2carboxylic acid, 272-273 7-Methyl-2-(toluene-4-sulfonyl)-1,2,3,4,4a,5hexahydro-[2]pyridin-6-one, 176 Michael functions acceptor, 388, 663 addiction, 386, 392, 394, 401, 582-583, 629, 656 adduct, 387 alkylation, 648-665 Michael/Michael/aldol condensation, 294 reaction, 181-182,398 Microreactors, 690 Microwave iraadiation (MWI), 152, 156, 546 Mitsunobu reaction, 442 MM2 calculations, 211 Mock's procedure, 11 Modhephene, 187 Molar refraction, 13 Molecular mechanics, 211 Molecular oxygen, 129 Molecular scaffolds, 280 Molecular structure theory, 688 Molybdenum, 157,309 Monoacylation, 613 Monoalkylation, 601

Index

Mono-thiol esters, Dieckmann condensation, 98-99 Moore cyclization description of, 356 experimental, 366-367 historical perspective, 356-357 mechanism, 357-358 synthetic utility, 362-366 variations and improvements, 358-362 Moore reaction, 379 Morpholine, 657 Morpholinones, 524 Morpholinoquinoline, 581 Mukayama-Michael reaction, 405 Muscone, 567 Mutagenicity, 252, 260-261 Mutisianthol, 344 Mycoepoxydiene, 550 Myers-Saito cyclization description of, 369 experimental, 384 historical perspective, 369-370 mechanism, 216-217, 219, 358, 370-372 synthetic utility, 378-383 variations and improvements, 372-378 N-acylcamphorsultan, 18 Nafoxidine, 262 Nakamurol A, 338 Nanaomycin D, 365 Naphthalenes, 240, 252, 267-269, 352, 372, 376377, 409, 442, 543-544, 603-604, 615, 619, 691 Naphthols, 311 Naphthoquinones, 279, 316, 364 Naphthoylpropionic acids, 342 l-(2-Naphthyl)pentan-l-one, 384 Naphthyls, 331 Naphtol, 309 Natural product synthesis Büchner reaction, 430 Dötz benzannulation, 318-321 Haworth reaction, 347-348 Robinson annulation, 404-405 Vilsmeier-Haack reaction, 707-708 Nazarov cyclization description of, 122-130, 133-137 experimental, 144-145 historical perspective, 122-123 mechanisms of, 123-126, 130-133

747

synthetic utility, 126-137 variations and improvements, 137-144 Nazarov reagent, 401 JV-Benzylidine-p-anisidine, 65 N-10-BOC-1 -prenyl-6-bromotryptamine, 670 Neocarzinostatin, 219, 382 Neo-clerodanes, 553 Neomycin B, 513 Neoplastic agents, 106 Neurological disorders, 519 Neurotransmitters, 21 Nicholas reaction, 166-167, 171 Nickel, 157 Nitriles, 16, 163, 293, 578-579, 601, 678, 682, 702 Nitrilium ion, 684 Nitroalkenes, 655 Nitroarene, 710 Nitrobenzene, 342, 614-615 Nitro groups, 171, 311, 600, 602, 710, 713 Nitrogen functions of, 13, 33, 45, 52, 91, 157, 166, 172, 174,282,287,302,511,631,680 molecular, 7 -protecting groups, 33 Nitroketone, 294 Nitrophenol, 691 Nitroquinolone, 713 Nitroso, 281 Nitroxide, 116 iV-methylmaleimide (NMM), 292-293 Af-methylmorpholine-7V-oxide (NMO), 154, 157, 175, 506 Nogalamycin, 241 Nominine, 299 Nonbonding interactions, 663 Nonsteroidal antiinflammatory (NSAID), 613 Norbornadiene, 147-148, 171 Norbornene, 149, 160-162, 164 Norrish reaction, 333 Nosyl protecting group, 635 N-oxides, Pauson-Khand reaction, 154 N-phosphino-p-tolyolsufinamide (PNSO), 159 Nuclear magnetic resonance (NMR) studies, 9, 245, 268, 465, 682 Nucleophiles auxiliary, 50 Favorskii rearrangement, 114, 117-118 functions of, 58, 338, 545, 606, 658 Nazarov cyclization, 141

748

Index

Nucleophiles (continued) nonaromatic, 703-704 Pauson-Khand reaction, 167 Nucleophilic(s) attack, 343, 591 impact of, 315, 426 rings, 202 Nucleophilicity, 14, 27-28, 47, 49, 110, 603, 678 Nucleosides carbocyclic, 102 functions of, 102 Nucleotide synthesis, 522 Obesity, 401 Octane systems, 181, 191 Octocycle, 553 Okadaic acid, 116 Okilactomycin, 565-566 Olefination, 186 Olefines, activated, 663 Olefins acyclic chiral, 32 characterized, 4, 10, 17, 19, 21-22, 25, 33, 37, 40 conversion to cyclopropanes, 24 cyclic, 29 cycloadditions, 45 de Mayo reaction, 460, 463, 467-468 electron-deficient, 530 metathesis, 506, 510-511, 513-514, 517, 521, 524-526, 528, 535-537, 539, 542-543, 547, 550, 556, 559, 566, 568 Nazarov cyclization, 129, 141 Pauson-Khand reaction, 155 photocycloadditions, 451-452 unfunctionalized, 38 Orbital symmetry, 124 Orcinol, 678 Organic chemistry, 193 Organocatalysts, 636, 662 Organometallics, 73, 216 Organozinc reagent, 37 Ortho rule, 277 Oseltamivir, 63-64 Ottelione, 517 Oxalyl chloride, 61 Oxazaborolidines, 284 Oxazolidinone, 55 Oxidation, 11, 19, 25, 27, 51, 55, 143, 172, 186, 193, 288, 293, 301, 359, 365, 410, 442, 447,

528-529, 534 Oxidative addition, 37 Oxindole, 436 Oxiranes, 617 Oxoglutarate, 181-182 ( 105,1 OaÄ)-10-(2-Oxopropyl)-2,3,10,10atetrahydropyrrolo[l,2-è]isoquinoline-l,5dione, 486 Oxyallyl cations, 133, 141 Oxyanions, 373-374 3'-Oxybutyl, 387 Oxychloride, 191 Oxygen, 31, 33, 40, 51, 56, 140, 142, 154, 680, 691 Oxygenation, 557, 560 Ozonolysis, 190, 192-193 Paclitaxel, 63 Paecilomycine, 168-169 Palladium, 129, 135, 142, 157, 203, 284 Pallavicinolide A, 299 Palominol, 299 Pancratistatin, 515 Paniculatine, 168-169 Parabens, 688, 694 Para-hydroxybenzoic acid, 695-696 Para rule, 277-278 Pauson-Khand reaction (PKR) description of, 147 experimental, 176 historical perspective, 147-148 mechanisms of, 148-152 synthetic utility, 160-176 variations and improvements, 152-160 Pederin, 296 Pentacene, 263 Pentadienyl cations, 131-133 Pentalene, 186 Pentalenene, 168-170,479-480 [(l,2,3,4,5--ri)-12,3,4,5-Pentamethyl-2,4cyclopentadien-1 -yl]Ru{ (3a,4,5,6,7,7a-T|)2,3 -dihy dro-6-methy 1-1 H-inden-5 yl)trimethylsilane})OTf, 220 Pentane, 22 3-Penten-2-one (EVK), 399,401 Pentaprismane, 117 Pentostatin, 103 Perfume industry, 477 Perhydrohistrionicotoxin, 584 Perhydroisoquinoline, 282

Index

Periplanone C, 516-517 Periselectivity, 50-51 Perrottentinene, 519 Petatis-Ferrier rearrangement, 568 pH, significance of, 154, 185 Pharmaceutical synthesis, 693-694 Pharmacophores, 240 Phenanthrene functions of, 271, 342-344, 615 synthesis, 205. See also Bardhan-Sengupta phenanthrene synthesis Phenanthridines, 684 Phenethylamine, 701 Phenethyl group, 202 Phenol groups, 519 Phenols, 309, 311, 315, 321, 360, 379, 595, 624625, 630, 680, 690 Phenones, Houben-Hoesch reaction, 681 Phenoxide, 689-690, 693 Phenyl(s) acetaldehyde, 251-252 acetylene, 147, 156 acid phosphate, 257-258 alanine, 55 cyclopropane, 7, 10, 12 diazomethane, 38 esters, 96 functions of, 183, 365, 370, 372,629, 707 groups, 10, 256, 272 naphthalene, 251 propanes, 617 propionate, 650 l-Phenyl-3-aminotetralins, 272 9-Phenylanthracene, 264-265 2-Phenylbicyclopropyl, 10, 13 2-Phenylcyclopropane methanol, 42-43 5-Phenyl-3-pyrazoline, 7 Phloroglucinol, 678-679 Phomactin, 320 Phorboxazole B, 296 Phoshatidylinositl 3 kinase, 528 Phosphatase, 528 Phosphates, 187 Phosphines, 153, 159,312 Phospholipases, 507 Phosphonates, 658 Phosphoric acid, 36, 204, 398, 637, 647, 668 Phosphorous pentoxide, 204 Phosphorus, 5, 200, 350, 383

749 Phosphoryl chloride, 698 Photo-Bergman cyclization, 212-213, 219-220 Photochemistry, 33-334, 452 Photocyclization, 595 Photocycloaddition, 451, 456, 461-466, 470 Photodimerization, 193,451 Photodynamic therapy, 529 Photo-Fries process, 477 Photoinduced cyclization, 212 Photolysis, 52, 215, 220 Physarorubinic acid, 106 Pictet-Spengler reaction, 64, 615, 638-639, 643-644, 646-647 Piperidines, 284, 286, 584 Piperidinones, 639, 642 Piperidinoquinones, 363 Pivaldehyde, 83 Pivaloylphenone, 611 PKC activators, 557 Planarization, 415 Plateau-type reactions, 184 Platinum, 172 Point-type reactions, 184 Polar diradicai, 370-371 Polio virus, 347 Polyalkylation, 600-601, 608-609, 615, 625-631 Polycyclic aromatic(s) compounds, 417 hydrocarbons (PAH), 260-261, 263 networks, 418 Polycycloketones, 388 Polyethers, 420 Polymerization, 419-420, 600, 608-609 Poly(phenylene), 419 Polyphosphoric acid (PPA) 198, 203, 205-206, 257, 268,612 Polyquinanes, 185 Polyquinene, 194 Porphyrins, 529 Potassium chromate, 220 functions of, 96, 690-691, 694 hydroxide, 12-13,402,470 Prolines, 55-56, 395 Promoters, 153,279-280 1,3-Propanediol, 4 Propane, 3 Propargyl azaeneynes, 377

750

Index

Propargyl (continued) characterized, 83 groups, 149 rearrangement, 375 Propene, 173 Propionitrile, 683 Propyl groups, 136 Prostacyclin (PGI2), 189 Prostaglandins, 139, 469, 506 Prostate cancer, 536 Protecting groups, 31, 33, 170, 460, 547, 613, 647 Protic acid, 122-123,127,198, 676 Protodesilyation, 86, 88-90, 139 Proton(s) functions of, 134, 140 loss, 252 Sponge, 58, 61 Protonation, 111, 118, 123,133,268,290,581,591, 637, 676, 683 Pseudopteroxazle, 405 Pteriatoxins, 299 Purines, 522 Pyrans, 296 Pyranone, 296 Pyrazlidonones, 284-285 Pyrazoles, 7, 311 Pyrazoline, 8, 10, 13 Pyridines, 46, 89, 282-283, 293, 596, 690, 692 Pyridinium, 268 Pyridium aza-enediynes, 378 Pyridyls, 10, 238, 257 Pyrimidine212,417, 707 Pyrimidyls, 417 Pyroglutamic acid, 60 Pyrolysis, 7, 46, 51, 210, 327, 332-333, 370 Pyrolytic cyclization, 238 Pyrroles, 289, 311,467, 580, 614, 629, 632, 655, 658, 660, 679, 705 Pyrrolidine, 283, 299, 401 Pyrrolidinones, 639, 642, 665 Pyrrolizinone, 85 Pyrrolohydroxylactams, 644 Pyrroloquinolizidine, 643-644 Pyruvates, 628, 630-632 Quelet reaction, 596 Quenching, 22, 42, 91, 141, 207, 315, 702 Quercitol, 512-514 Quinazolidinone, 641

Quinazoline, 684 Quinic acid, 523-524 Quinines, 364 Quinodimethane, 380 Quinolones, 522, 639, 646 Quinones, 203, 285, 296, 311,315,318, 321,357358,363,365,558-561,568 Racemization, 105 Radical cations, 410-412,416 Radical cyclization, 362 Ramewaralide, 537-538 Raney nickel, 98, 442 Rapoport regioselective Dieckmann condensation, 103-104 Rate-determining step (RDS), 113, 603, 610 Rayonette photochemical reactor, 220 (Ä)-l-benzyl-5-(l//-indol-3-yl)pyrrolidin-2-one, 668-669 Rearomatization, 591, 646 Rearrangements, 329-332, 600-601, 606-607 Reduction process, 193 Refractive index, 6 Regiochemistry de Mayo reaction, 454 Dötz benzannulation, 320-321 Kolbe-Schmitt reaction, 691 Pauson-Khand reaction, 149-150, 163, 165-166, 168, 173 von Richter reaction, 710 Regioselectivity Blanc chloromethylation reaction, 593, 596 Büchner reaction, 436 de Mayo reaction, 454-455, 458-460, 470 Dieckmann condensation, 28-29 Diels-Alder reaction, 276 Friedel-Crafts acylation, 613-614 Friedel-Crafts alkylation, 615-616, 620 Friedel-Crafts reactions, 662 Houben-Hoesch reaction, 677, 680 Pauson-Khand reaction, 156, 160-161, 165, 173 Scholl reaction, 419 Simmons-Smith cyclopropanation, 28-29 Vilsmeier-Haack reaction, 700-701, 704-705 Reprotonation, 136 Resorcinol, 678 Retroaldolization, 458-460 Retro-Bergman reaction, 213 Retro-cyclization, 132-133

Index

Retrocycloaddition, 531 Retro-Dieckmann reaction, 94 Retro-Diels-Alder reaction, 147, 171, 279, 293 Retro-Friedel-Craft alkylation, 608 Retro-Mannich fragmentation, 466-467 Retrosynthetic analysis theory, 477 Reverse transcriptase, 681 Reversible Dieckmann reaction, 94 R groups, 123 Rhizosphere, 534 Rhodium, 157, 217, 392, 425, 427-428, 433, 436440, 442, 446 Ribofuranosides, 512 Ring-closing metathesis (RCM) strategy description of, 489 experimental, 569-570 historical perspective, 489-490 mechanism, 490-491 synthetic utility, 494-569 variations and improvements, 492-494 Ring closure, see Ring-closing metathesis (RCM) strategy conrotatory, 47, 124 direct, 49 disrotatory, 47, 124 electrocyclic, 140 (R)-1 -( 1 -methyl- l//-imidazol-2-yl)-2-(2,3,4,9tetrahydro-1 //-carbazol-1 -yl)ethanone, 669670 Robinson annulation description of, 386 experimental, 405-407 historical perspective, 386 mechanism, 386-388 standard method, variations, and improvements, 388-400 synthetic utility, 400-405 Robinson-Cornforth route, 404 Robinson-Mannich annulation reaction, 388 Roseophilin, 564-565 Rotenic acid, 693 Rubidium, 690 Rubioncolin B, 301 Rule of fives, 457 Ruthenium, 157, 214, 217, 432, 528 Sakyomicin A, 242 Salts acridinium, 246

751 acylammonium, 51 ammonium, 61, 236, 594 carbonic, 690 iminium, 698, 700, 702 indium(III), 269 isoquinolinium, 239-242, 245 metal, 214 naphthyridium, 243-244 nitrilium, 682 paraben, 689 phenoxide, 690 potassium, 689, 691 salicylate, 689 triazinium, 676 Vilsmeier, 704-705 Samarium, 32, 39-40 SAMP, 55 Saponification, 61, 109, 351, 457, 470 Sarcodictyin, 558 Sarcophytoate, 297 Sativene, 477-478 Saudin, 452, 484-485 Saytzeff's Rule, 125 (S)-Azabis(oxazoline), 653 (5)-6-Bromo-8-(3-prenyl)-31 -(3-oxo-propyl)3,3a,8,8a-tetrahydro-2#-pyrrolo[2,3b] indole- 1-carboxylie acid iert-butyl ester, 670 Scandium, 87, 135 Schlenk equilibria, 26 Schmitt modification, 690 reaction, 297 Schmittel cyclization, 371-374, 377 Scholl reaction description of, 409 experimental, 420-421 historical perspective, 409-410 mechanism, 410-412 synthetic utility, 412-420 variations and improvements, 412 Selectivity, 204-205. See also Enantioselectivity; Regioselectivity; Stereoselectivity; Torquoselectivity Seleninic acid, 375 Selenium, 203 Selenoxide, 186 Selenyl groups, 200, 311 Semibenzylic pathway, 112-114

752

Index

Semibull valene, 191 Serine, 545 Serotonin reuptake inhibitor (SRI), 665 Sesquiterpenes, 508, 521 Sesquiterpenoids, 188 Sesquiterterpenes, 539 Seven-membered rings, ring-closing metathesis strategy, 530-544 Sigmatropic rearrangement, 381, 384 Silanes, 88, 172 Silica, 153-154 Silica gel chromatography, 42 Silicon groups, 32 Siloxydienes, 287, 295 Silphinene, 138 Silver, 382, 384 Silxacyclopentenes, 288 Silyl(s) alkenes, 88-90 allenes, 72, 74-76, 78-84, 86-87 characterized, 292 cyclopentene, 72, 88 enol ethers, 27, 391-392, 403, 405, 461, 468, 472475,509-510,530 ethers, 153,299-300 furan, 92 groups, 75, 77-78, 84, 122, 139, 155, 166, 389 Silylation, 190 Simmons-Smith cyclopropanation asymmetric reactions, 24, 33-43 description, 24 experimental, 41-43 historical perspective, 24-25 mechanism, 25-27 regioselectivity, 28-29 stereoselectivity, 28-29 synthetic utility, 27-33 variations and improvements, 37-40 Six-membered carbocycles Bardhan-Sengupta phenanthrene synthesis, 198208 Bergman cyclization, 209-220 Bogert-Cook reaction, 222-234 Bradsher cycloaddition and Bradsher reaction, 236-249 Bradsher reaction, 251-265 Darzens synthesis of tetralin derivatives, 267-274 Diels-Alder reaction, 275-304 Dötz benzannulation, 309-322

Elbs reaction, 324-334 Fujimoto-Belleau reaction, 336-340 Haworth reaction, 342-353 Moore cyclization, 356-367 Myers-Saito cyclization, 369-383 Robinson annulation, 386-407 Scholl reaction, 409-421 Six-membered rings, ring-closing metathesis strategy, 509-529 Skytanthine, 168-169, 171 (■S)-Methionine, 64 (S)-N-( 1 -(4-Hydroxy-1 //-indol-3 -yl)-1 phenylethyl)acetamide, 668 Soap industry, 4 Sodamide, 583 Sodiocyclohexanone, 386 Sodium, see Salt(s) bicarbonate, 59, 65-66 bis(trimethylsilyl)amide, 59 dioxide, 60 effects of, 2, 691 erythorbate, 53 ethoxide, 388 sulfate, 12 Solid-phase Dieckmann condensation, 104 Solvent(s), see specific types of reactions Sonication, 152 Sorbose, 513 Spectroscopic studies Kolbe-Schmitt reaction, 689-690 Myers-Saito reaction, 376 Simmons-Smith cyclopropanation, 26 Spin correlation effect (SCE), 211 Spirane, 199,202 Spirocarbocycles, 524 Spirocycles, 520-522, 524 Spirocyclopentene, 86 Spiroimines, 541 Spiroketals, 280 Spiroketones, 358, 583 Spirolactams, 541 Spiropiperidine 584 Stannyl groups, 122, 139, 311 Staudinger ketene-imine cycloaddition asymmetric, 58-59, 65 description of, 45 enantioselective methods, 52-60 experimental, 64-66 historical perspective, 45

753

Index mechanisms of, 45-47 periselectivity, 50-51 stereochemical outcome, 47-50 synthetic utility, 60-64 variations and improvements, 51-52 Stauranes, 193 Stereochemistry Bardhan-Sengupta phenanthrene synthesis, 205206 Danheiser annulation, 77-78 Dötz benzannulation, 317, 319, 321 Friedel-Crafts alkylation, 634 Kishner cyclopropane synthesis, 7-8 Kulinovich cyclopropanol synthesis, 16 Nazarov cyclization, 131, 134-136 Pauson-Khand reaction, 148-149, 157, 160, 174 ring-closing metathesis, 527 Robinson annulation, 396-397 Simmons-Smith cyclopropanation, 32 Weiss-Cook reaction, 190 Stereocontrol, 644-645, 649-652, 660-661 Stereoelectronics, 40 Stereoinduction, 633 Stereoisomers, 29, 32,401 Stereoselectivity Büchner reaction, 426, 442 Darzens synthesis, 270 Diels-Alder reaction, 276-277, 290 Favorskii rearrangement, 110, 118 Friedel-Crafts alkylation, 616, 620, 622, 633 Friedel-Crafts reactions, 658, 663 Nazarov cyclization, 140 Pauson-Khand reaction, 164, 170 ring-closing metathesis, 551 Robinson annulation, 400 Simmons-Smith cyclopropanation, 24-25, 28-29, 37 Steroids, 199,206,339,507 Sterols, 386 Sterpurene, 113 Stibene, 451 Stoichiometric studies asymmetric Simmons-Smith reaction, 34, 36 Bardhan-Sengupta cyclization, 200 Blanc chloromethylation reaction, 592 Dieckmann condensation, 100 Friedel-Crafts alkylation, 624 Friedel-Crafts reactions, 635 Nazarov cyclization, 122, 128

Pauson-Khand reaction, 150, 153 Simmons-Smith reaction, 38 Stork-Danheiser alkylation, 72 Stork-Enamine ketones, 390 Stork-Jung vinylsilanes, 389-390 (5)-3,3,3-Trifluoro-2-hydroxy-2-(5-methyl-3indolyl)-propionic acid ethyl ester, 667-668 Structure-activity relationship, 694 Styrenes, 703 Styryl cyclopropyl, 10, 12 Substrates acylic, 31-32, 38 cyclic, 31 cyclopropanating, 27 Favorskii rearrangement, 111 Nazarov cyclization, 130-133 olefin, 26 Simmons-Smith cyclopropanation, 24 Simmons-Smith reactions, 27 Succinic(s) anhydride, 342, 345-346, 349, 351 ester-amide, 16 Sugars, 53,218,294,339,512 Sugasawa reaction, 677, 680-681 Sulfates, 600 Sulfenylinium, 639 Sulfide groups, 311 Sulfides, 153, 155, 159 , 312, 600, 602 Sulfonamides, 153, 167 Sulfonamido enediynes, 214 Sulfones, vinyl, 164 Sulfonyl azide, 52 Sulfoxides, 159 Sulfur, 158,581 Sulfurane, 187 Sulfur dioxide, 46, 246, 601 Sulfuric acid, 122,267-269 Sulphur, 159 Sulphuric acid, 251 Sundiversiflide, 536 Superstolide A, 302 Suprafacial attack, Danheiser annulation, 77 Suzuki-Miyaura coupling, 419 Symbioimine, 299 Syncytia, 567 Synthesis, organic, 181, 246, 279, 520 Synthetic chemistry, 45 Tandem Diels-Alder reactions, 293-295, 297

754

Index

Tarchonanthuslactone, 20 Tartaric acid, 33 Tartrate, 168 Tashiromine, 708 Tautomerization, 123, 310, 317, 325-326, 374 Taxane, 481-482 Taxoids, 514 Taxol, 28, 553, 558, 562-563 Taxuspines, 562-563 Temperature influential factors, 3 reaction, 50 significance of, 11-12, 137-138, 151, 175,312, 315, 329, 366, 381, 596, 651-652, 660, 664 Termites, control strategies, 541 Terpenes, 515, 536, 538-539 Terpenoids, 477, 536 Terpestacin, 567 iert-Butyl-(cyclopent-3-enyloxy)-dimethy-silane, 569-570 [(4Z)-8-ieri-Butyldimethylsiloxy-1 -(tert)butyldimethylsilyloxymethyl)octa-1,2,4trien-6-yn-1 -yl](diphenyl)phosphine oxide, 384 {2-iert-Buty ldimethyl-silyoxy-1 -[2-(tertbutylmethyl-silyloxy- \-[2-tertbutydimethylsilyloymethyl)phenyl]ethyl} (di phenyl)-phosphine xide, 384 Testosterone, 336, 339 Tetracyanoethylene (TCNE), 237 Tetrahdyrocannabinol, 519-520 Tetrahydrofuran (THF), 22, 61, 89, 174 Tetrahydroisoquinolines, 287 Tetrahydronaphthalene, 267, 269-270 Tetralins, 239-240 Tetralone, 272, 428-429 2,2,3,3-Tetramethylmethylenecyclopropane, 11 3,3,5,5-Tetramethyl-4-methylene-l-pyrazoline, 11 Tetramethyl-4-pyrazolidone, 11 Tetronasin, 106 Tetronates, 471-472 Tetronic acids, 106 Teubrevin, 552-553 Thapsigargins, 536 Thermal cyclization, 124, 219 Thermal Diels-Alder reaction, 297-298 Thermodynamic effects, 129, 135, 137, 148, 183, 601,604,606,615,620,648

Thermolysis, 9-11, 211, 216-217, 358 Thiazolidine, 56, 62 Thiazoline, 31 Thieno[2,3,-/i5,4-/']bis[l]benzothiophene, 265 Thienopyridines, 581 Thienyls, Weiss-Cook reaction, 183 Thin layer chromatography, 157,174, 219 Thioaldehydes, 702 Thioalkyl groups, 173 Thiocyanates, 600, 602 Thioesters, 101, 655 Thiohalenaquinone, 528-529 Thiolactams, 392-393 Thiols, 97-98, 172, 600, 602 Thiophenes, 100, 167, 311, 597 Thiophenol, 647 Thioredoxin, 283 Thioureas, 155, 636, 639, 644, 655, 668-669 Thorpe-Ingold effect, 646 Thorpe-Ziegler cyclization description of, 578 experimental, 586-587 historical perspective, 578 mechanism, 579 synthetic utility, 580-586 variations and improvements, 579-580 Three-membered carbocycles Freund reaction, 2-6 Kishner cyclopropane synthesis, 7-13 Kulinovich cyclopropane synthesis, 14-23 Simmons-Smith cyclopropanation, 25-43 Threonine, 55, 57 Thrombin, 525 Thromboxane, 597 Thymol, 693 Ti-Dieckmann condensation, 99-101 Titanacyclopropane, 14 Titanium -carbon bond, 14-15 functions of, 14-16, 18,75-76, 157 TADDOL complex, 36 tetrachloride, 140 Titanoxacyclopentane, 14 Toluene, 61, 208, 302, 369, 399, 439, 532 12-m-Tolyl-benzo[a]anthracene, 249 Topliss' synthesis, 206 Torquoselectivity, 125-126, 133, 139 Tosyl groups, 311 Transalkylation, 606-608

755

Index

Transannular process, 302 Trans-2-berayl-1 -methyIcyclopropan-1 -ol, 22-23 Transcription factor, 560 Trans-1,2-dialkylcyclopropanol, 17 Trans-1,2-dimethyl-cyclopropane, 10 7rarts-3,5-dimethyl-l-pyrazole, 10 7ra/w-dihydroconfertifolin, 27-28 Trans-ethy 1-2-vinylcyclopropane, 10 Transformations of carbocycles asymmetric Friedel-Crafts reactions, 600-670 Blanc chloromethylation reaction, 590-598 Houben-Hoesch reaction, 675-685 Kolbe-Schmitt reaction, 688-696 Vilsmeier-Haack reaction, 698-709 von Richter reaction, 710-715 Transition metals, 280, 427-434 Trans-1 -(4-methoxyphenl)-4-phenyl-3(phenylthio)azetidin-2-one, 65 7rans-pyrazoline, 8-9 Trapping intramolecular, 142, 240 oxygen, 143 reductive, 140-141 6-end, 141 Tricycloillicinone, 518-519 Triethylamine, 50 Triethyl silane, 141 Trifluoroacetics acid, 38, 268, 270 ester, 43 Trifluoroethanol, 133 2 '4 ' 6 ' -Trihydroxy-2-methoxyacetophenone, 684685 Trimethylamino—iV-oxide (TMANO), 154, 156157, 162, 175 1,1,2-Trimethylcyclopropane, 4 Trimethylene(s) bromide, 2-3 characterized, 7-8 Trimethylsilyl, 139 Triquinacene, 192-193 Triquinanes, 138, 170,508 Trisallylcarvone, 518 Trisoxazoline (TOX), 651-652 Tryptamines, 639, 641,645-647, 654 Tryptophan, 172 Tumor cell lines, 558 Tumorigenicity, 261 Tungsten, 153, 157,309

Tyrosine kinase, 528 Ultrasonication, 316 Ultrasound, 153, 156 Uncialamycin, 288 Valienamine, 513-514 Valine, 57 Venereal diseases, 584 Versicolamide B, 302 Vilsmeier-Haack reaction description of, 698 experimental, 708-709 historical perspective, 698-699 mechanism, 700-701 synthetic utility, 704-708 variations, improvements, and modifications, 701-704 Vilsmeyer formylation, 271 Vilsmeier reagents, 447, 699-700, 704 Vindorosine, 302, 452, 482-483 Vineomycinone, 240 Vinyl bromide, 27 carbene, 311 chlorides, 74, 510 cyclopropane, 188 diazomethane, 9 groups, 313 halides,27,518, 521 indoles, 285 ketones, 390-393, 531 lithium, 113 phosphonate, 339 quinone, 299 silanes, 389-390 sulfoxides, 585 thiol products, 101-102 Vinylidene(s) complex, 216-217 diene, 296 Vitamin D, 554 Volatiles, 220 von Richter reaction description of, 710 experimental, 715 historical perspective, 710 mechanism, 710-712 synthetic utility, 714

756 von Richter reaction (continued) variations and improvements, 713-714 Wadsworth-Horner-Emmons reaction, 189 Wagner-Meerwin shifts, 124 Wailupemycins, 116 Warfarin, 649 Water, 2, 5, 12, 154-155, 174 Weinreb amide, 96 Weiss-Cook reaction description, 181 experimental, 195 historical perspective, 181 mechanisms of, 181 -184 synthetic utility, 185-195 variations and improvements, 184-185 Wieland-Miescher ketone, 395, 397 Wittig coupling, 633 olefination, 186 reaction, 189,595 Wolff rearrangement, 51, 60, 64-65, 448 Wolff-Kishner deoxygenation, 186 reduction, 343, 345

Index

Woodward-Hoffman rules, 47, 276, 279 Wulff-Dötz reaction, 310 Wurtz reaction, 2 X-ray crystal structures, 151-152 Xylenes, 612 Yb(III)-BINAMIDE complex, 291 Ylides, 595 Yohimbine, 299, 639 Zeolites, 609 Zinc alkoxide, 40 characterized, 2-6, 25-26, 512 chloride, 27 -copper couple, 24-25, 27 diethyl, 25-26, 32, 37 iodide, 26, 38-39 phosphate reagents, 36 reagents, 33, 36 Zirconium, 138, 157 Zizaene, 478-479, 541 Zwitterion, 45-46, 49, 58, 112, 371